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OXFORD MEDICAL PUBLICATIONS
Oxford Handbook of
Medical Imaging
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Published and forthcoming Oxford Handbooks Oxford Handbook for the Foundation Programme 3e Oxford Handbook of Acute Medicine 3e Oxford Handbook of Anaesthesia 3e Oxford Handbook of Applied Dental Sciences Oxford Handbook of Cardiology Oxford Handbook of Clinical and Laboratory Investigation 3e Oxford Handbook of Clinical Dentistry 5e Oxford Handbook of Clinical Diagnosis 2e Oxford Handbook of Clinical Examination and Practical Skills Oxford Handbook of Clinical Haematology 3e Oxford Handbook of Clinical Immunology and Allergy 2e Oxford Handbook of Clinical Medicine—Mini Edition 8e Oxford Handbook of Clinical Medicine 8e Oxford Handbook of Clinical Pharmacy Oxford Handbook of Clinical Rehabilitation 2e Oxford Handbook of Clinical Specialties 8e Oxford Handbook of Clinical Surgery 3e Oxford Handbook of Complementary Medicine Oxford Handbook of Critical Care 3e Oxford Handbook of Dental Patient Care 2e Oxford Handbook of Dialysis 3e Oxford Handbook of Emergency Medicine 3e Oxford Handbook of Endocrinology and Diabetes 2e Oxford Handbook of ENT and Head and Neck Surgery Oxford Handbook of Expedition and Wilderness Medicine Oxford Handbook of Gastroenterology & Hepatology 2e Oxford Handbook of General Practice 3e Oxford Handbook of Genetics Oxford Handbook of Genitourinary Medicine, HIV and AIDS 2e Oxford Handbook of Geriatric Medicine Oxford Handbook of Infectious Diseases and Microbiology Oxford Handbook of Key Clinical Evidence Oxford Handbook of Medical Dermatology Oxford Handbook of Medical Sciences Oxford Handbook of Medical Statistics Oxford Handbook of Nephrology and Hypertension Oxford Handbook of Neurology Oxford Handbook of Nutrition and Dietetics 2e Oxford Handbook of Obstetrics and Gynaecology 2e Oxford Handbook of Occupational Health Oxford Handbook of Oncology 3e Oxford Handbook of Ophthalmology 2e Oxford Handbook of Paediatrics Oxford Handbook of Pain Management Oxford Handbook of Palliative Care 2e Oxford Handbook of Practical Drug Therapy 2e Oxford Handbook of Pre-Hospital Care Oxford Handbook of Psychiatry 2e Oxford Handbook of Public Health Practice 2e Oxford Handbook of Reproductive Medicine & Family Planning Oxford Handbook of Respiratory Medicine 2e Oxford Handbook of Rheumatology 3e Oxford Handbook of Sport and Exercise Medicine Oxford Handbook of Tropical Medicine 3e Oxford Handbook of Urology 2e
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Oxford Handbook of
Medical Imaging Edited by
Michael J. Darby Consultant Radiologist Leeds Teaching Hospitals NHS Trust Leeds, UK
Dominic A. Barron Consultant Radiologist Leeds Teaching Hospitals NHS Trust Leeds, UK
Rachel E. Hyland Consultant Radiologist Leeds Teaching Hospitals NHS Trust Leeds, UK
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Great Clarendon Street, Oxford OX2 6DP Oxford University Press is a department of the University of Oxford. It furthers the University’s objective of excellence in research, scholarship, and education by publishing worldwide in Oxford New York Auckland Cape Town Dar es Salaam Hong Kong Karachi Kuala Lumpur Madrid Melbourne Mexico City Nairobi New Delhi Shanghai Taipei Toronto With offices in Argentina Austria Brazil Chile Czech Republic France Greece Guatemala Hungary Italy Japan Poland Portugal Singapore South Korea Switzerland Thailand Turkey Ukraine Vietnam Oxford is a registered trade mark of Oxford University Press in the UK and in certain other countries Published in the United States by Oxford University Press Inc., New York © Oxford University Press, 2012 The moral rights of the authors have been asserted Database right Oxford University Press (maker) First published 2012 All rights reserved. No part of this publication may be reproduced, stored in a retrieval system, or transmitted, in any form or by any means, without the prior permission in writing of Oxford University Press, or as expressly permitted by law, or under terms agreed with the appropriate reprographics rights organization. Enquiries concerning reproduction outside the scope of the above should be sent to the Rights Department, Oxford University Press, at the address above You must not circulate this book in any other binding or cover and you must impose the same condition on any acquirer British Library Cataloguing in Publication Data Data available Library of Congress Cataloguing-in-Publication Data Darby, Michael (Michael J.) Oxford handbook of medical imaging/Michael Darby, Dominic Barron, Rachel Hyland. p. ; cm.—(Oxford handbooks) Handbook of medical imaging Includes index. ISBN 978–0–19–921636–9 (alk. paper) I. Barron, Dominic. II. Hyland, Rachel. III. Title. IV. Title: Handbook of medical imaging. V. Series: Oxford handbooks. [DNLM: 1. Diagnostic Imaging—Handbooks. WN 39] LC classification not assigned 616.07’57—dc23 2011033024 Typeset by Cenveo, Bangalore, India Printed in China on acid-free paper through Asia Pacific Offset ISBN 978–0–19–921636–9 10 9 8 7 6 5 4 3 2 1
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Preface Radiology is becoming more and more important in the initial diagnosis, follow up, and, increasingly, the treatment of patients. At the same time it becomes more complex, and covers every anatomical and organ system group. This book is written using a system-based approach, covering the various modalities and explaining their relevance in each situation. For each system there are three separate sections. The first deals with common presenting symptoms, listing the most likely diagnoses. There is then a review of the imaging approach to each of these presenting conditions and the value of each modality. The second section lists the common radiological findings which may be encountered and the differential diagnoses which need to be considered. The final section discusses in detail a number of common conditions. Using this approach, the authors hope that this book will help to guide junior doctors and other professionals through the increasingly varied roles imaging can play in the management of their patients. With a book of this size, it is impossible to include all known conditions. The authors have concentrated on those conditions which are either common, or of such importance that any delay in diagnosis may be significant. The authors would value feedback on the text which could lead to improvements being made in future editions.
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Acknowledgements In preparing the text, the authors are aware that many of the lists, statistics used, and radiological signs described have previously been published. Acknowledgement is made to the following texts: Chapman S. Nakielny R. Aids to Radiological Differential Diagnosis, 5th edition. Philadelphia: WB Saunders, 2009. Dähnert W. Radiology Review Manual, 7th revised international edition. Baltimore: Lippincott Williams & Wilkins, 2011.
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Contents Contributors ix Symbols and abbreviations xi 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23
Techniques Respiratory differential diagnosis Respiratory presenting syndromes Respiratory conditions Vascular differential diagnosis Vascular presenting syndromes Vascular conditions Neurology differential diagnosis Neurology presenting syndromes Neurology conditions Head and neck differential diagnosis Head and neck presenting syndromes Head and neck conditions Genitourinary differential diagnosis Genitourinary presenting syndromes Genitourinary conditions Musculoskeletal differential diagnosis Musculoskeletal presenting syndromes Musculoskeletal conditions Trauma Gastrointestinal differential diagnosis Gastrointestinal presenting syndromes Gastrointestinal conditions
1 23 27 41 93 97 101 133 137 141 169 171 175 199 203 215 257 259 265 311 341 345 357
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CONTENTS
24 Breast differential diagnosis 25 Breast conditions
413 415
Index 431
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Contributors Raneem Albazaz
Nalinda Panditaratne
SpR Leeds Bradford Radiology Training Scheme, UK
SpR Leeds Bradford Radiology Training Scheme, UK
Anu Balan
Sabrina Rajan
Consultant Radiologist Addenbrookes Hospital Cambridge University Hospitals NHS Foundation Trust Cambridge, UK
SpR Leeds Bradford Radiology Training Scheme, UK
Priya Bhatnagar Leeds Teaching Hospitals NHS Trust, Leeds, UK
Robert Briggs Consultant Radiologist Calderdale and Huddersfield NHS Foundation Trust, UK
Barbara Dall Consultant Breast Radiologist Leeds Teaching Hospitals NHS Trust Leeds, UK
Karen Flood SpR Leeds Bradford Radiology Training Scheme, UK
Nerys Forrester SpR Leeds Bradford Radiology Training Scheme, UK
Shishir Karthik SpR Leeds Bradford Radiology Training Scheme, UK
Amit Lakkaraju Musculoskeletal Radiology Fellow Royal Liverpool Hospital Prescott St, Liverpool, UK
Emma Rowbotham SpR Leeds Bradford Radiology Training Scheme, UK
Nisha Sharma Director of Breast Screening Leeds/Wakefield Breast Screening unit, UK
Stephen Slater SpR Leeds Bradford Radiology Training Scheme, UK
Gemma Smith Consultant Radiologist Bradford Teaching Hospitals NHS Foundation Trust, UK
Manil Subesinghe SpR Leeds Bradford Radiology Training Scheme, UK
Sophie Swinson SpR Leeds Bradford Radiology Training Scheme, UK
Stuart Viner Consultant Radiologist Bradford Teaching Hospitals NHS Foundation Trust, UK
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Oxford University Press makes no representation, express or implied, that the drug dosages in this book are correct. Readers must therefore always check the product information and clinical procedures with the most up-to-date published product information and data sheets provided by the manufacturers and the most recent codes of conduct and safety regulations. The authors and publishers do not accept responsibility or legal liability for any errors in the text or for the misuse or misapplication of material in this work. Except where otherwise stated, drug doses and recommendations are for the non-pregnant adult who is not breastfeeding.
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Symbols and abbreviations b 8 ± A B G 2D 3D ABG ACE AP AS ASD ATN AV AVF AVM AVN BSO Ca CC CEA CM CMCJ COPD CRP CT CTA CTPA CTU CXR DCBE DCM DIPJ DMSA DRE
cross-reference approximately with or without alpha beta gamma 2-dimensional 3-dimensional arterial blood gases angiotensin converting enzyme anteroposterior aortic stenosis atrial septal defect acute tubular necrosis arteriovenous arteriovenous fistula arteriovenous malformation avascular necrosis bilateral salpingo-oophorectomy calcium craniocaudal carcinoembryonic antigen cardiomyopathy carpometacarpal joint chronic obstructive pulmonary disease C-reactive protein computed tomography computed tomography angiography computed tomography pulmonary angiography CT urogram chest X-ray double-contrast barium enema dilated cardiomyopathy distal interphalangeal joint dimercaptosuccinic acid digital rectal examination
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SYMBOLS AND ABBREVIATIONS
DTPA DVT DWI EAA ECG EF e.g. ERCP ESR EUS FAST Fbc FDG FIGO FLAIR GCS GCT GI GU HCC HCG HCM HPT HRCT HRT HU IMB INR IV IVC IVU JVP keV KUB LBO LFT LMP LN LVF
diethylene triamine pentaacetic acid deep vein thrombosis diffusion-weighted imaging extrinsic allergic alveolitis electrocardiogram ejection fraction for example endoscopic retrograde cholangiopancreatography erythrocyte sedimentation rate endoscopic ultrasound focused assessment with sonography for trauma or face arm speech test full blood count fluorodeoxy-D-glucose International Federation of Gynaecology and Obstetrics fluid attenuated inversion recovery Glasgow Coma Score germ cell tumour gastrointestinal genitourinary hepatocellular carcinoma human chorionic gonadotropin hypertrophic cardiomyopathy hyperparathyroidism high resolution computed tomography hormone replacement therapy Hounsfield unit intermenstrual bleeding international normalized ratio intravenous inferior vena cava intravenous urogram jugular venous pressure kilo-electron volts kidneys, ureters, bladder large-bowel obstruction liver function tests last menstrual period lymph node left ventricular failure
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ml mg m/s MAG3 MC&S MCPJ MCUG MDP Mg MHz MI MIBG MLO MR MRCP MRE MRI MS mSv NCCT NG NICE NJ NSAID OGD OHCM PA PACS PCD PCI PDA PET PIPJ PMB PMF PSA RCM RTA SAH SBFT
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millilitre/s milligram/s metres per second mercapto acetyl triglycerine microscopy, culture, and sensitivity metacarpophalangeal joint micturating cystourethrogram methyl-di-phosphonate magnesium megahertz myocardial infarction metaiodobenzylguanidine mediolateral oblique magnetic resonance or mitral regurgitation magnetic resonance cholangiopancreatography magnetic resonance enterography magnetic resonance tomography mitral stenosis millisievert non-contrast computed tomography nasogastric National Institute for Health and Clinical Excellence nasojejunal non-steroidal anti-inflammatory oesophagogastroduodenoscopy Oxford Handbook of Clinical Medicine, eighth edition (2010) posteroanterior picture archive communication systems peripheral vascular disease primary percutaneous intervention patent ductus arteriosus positron emission tomography proximal interphalangeal joint postmenopausal bleeding progressive massive fibrosis prostate specific antigen restrictive cardiomyopathy road traffic accident subarachnoid haemorrhage small bowel follow through
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SYMBOLS AND ABBREVIATIONS
SLE SPECT SSRI SUV TA TB Tc TCC TMN TOE TRUS TURP TV U&E UC Uro UTI VQ VSD WCC
systemic lupus erythematosus single-photon emission computed tomography selective serotonin reuptake inhibitor standardized uptake value transabdominal tuberculosis technetium transitional cell cancer tumour, node, metastasis transoesophageal echocardiography transrectal ultrasound transurethral resection prostate transvaginal urea and electrolytes ulcerative colitis urological urinary tract infection ventilation/perfusion ventricular septal defect white cell count
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Chapter 1
Techniques Plain film radiography 2 Fluoroscopy 4 Angiography 6 Ultrasound 8 Computed tomography 10 Nuclear medicine (traditional) 12 PET-CT 16 Magnetic resonance imaging 18 Interventional radiology 20
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Plain film radiography The electromagnetic spectrum is comprised of different types of radiation, which all travel at the same velocity in a vacuum, 3 × 108m/s (speed of light), but which vary in their frequency, wavelength, and energy. Plain film radiography utilizes X-rays, which are a type of ionizing radiation owing to their extremely short wavelengths and high energies. Using X-ray tubes, electrons produced by thermionic emission from the negatively charged cathode are accelerated towards the positively charged anode. These fast moving electrons interact with the atoms of the metallic anode and by doing so their kinetic energy is converted into X-rays (1%) and thermal energy (99%). Most diagnostic radiology sets have anodes made of a tungsten–rhenium alloy but in mammography either molybdenum or rhenium is used. X-rays that travel through the tissues of the body can be absorbed or scattered. Both these processes contribute to attenuation of the primary X-ray beam. X-rays that are transmitted through the patient reflect a varying degree of attenuation, which is dependent upon several factors including the atomic numbers and physical densities of the materials traversed in addition to the initial energies of the incident primary X-ray beam. The final radiographic image is formed entirely of transmitted X-rays. Until very recently, radiographic film was used to display the final image. X-rays that have passed through air are minimally attenuated and therefore maximally transmitted, causing film blackening. X-rays that have passed through bone are heavily attenuated with very few transmitted, resulting in minimal film exposure and a resultant white appearance. Most modern radiology departments now use digital radiographic acquisition in conjunction with picture archiving communication systems (PACS). Digital image plates replace radiographic film with computers playing a fundamental role in post-processing and storage. The final image is then displayed on a dedicated viewing monitor. Although plain film radiography utilizes ionizing X-ray radiation, the effective doses for the majority of examinations performed are low in comparison to computed tomography (CT). It is cheap, readily accessible, and easy to perform and for these reasons is commonly the first-line imaging modality utilized by clinicians. The main applications of plain radiography are initial investigation of the thorax, abdomen, and skeletal system, in particular trauma and joint-based disease (Fig. 1.1). Despite its high spatial resolution, the major disadvantage of radiography is its poor soft tissue contrast resolution, which is where other modalities such as magnetic resonance imaging (MRI) and CT, to a lesser extent, are more useful.
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(a)
(b) Fig. 1.1 a) AP radiograph of the ankle joint demonstrating a multisegmental fracture of the distal tibia and fibula. b) Chest radiograph demonstrating generalized patchy shadowing throughout both lungs and a central line in a 20-year-old with cystic fibrosis.
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Fluoroscopy Historically the first mode of medical imaging to use ionizing radiation, dating back to 1895. The patient was placed between an X-ray source and the observing radiologist looked down a tube with a fluoroscopic coating, unfortunately with substantial radiation to the radiologist. Thankfully monitors were introduced to display images obtained by intensifier units. Fluoroscopy uses rapid pulses or streams of X-rays to produce a real-time image rather like a moving radiograph. The devices can be angled or moved in 3 dimensions to achieve optimal views to demonstrate pathology. Fluoroscopy has a role in both diagnostic and procedural work, including vascular intervention and use in operating theatres. Orthopaedics use screening to align fixation plates and reduce fractures. Musculoskeletal (MSK) radiologists use it to perform arthrograms and injections. Gastrointestinal (GI) and urological (Uro) radiologists use screening (see ‘Imaging’). Contrast agents are central to GI and Uro radiology fluoroscopy: • Positive agents such as barium and iodine block X-rays; pathology often appears as a filling defect within the contrast. • Negative agents (air and water) distend structures/lumens and allow more X-rays through. • Double-contrast techniques utilize both of the above and allow surfaces to be visualized in detail (Fig. 1.2), e.g. bowel mucosa.
Imaging Visualization of the GI tract lends itself well to fluoroscopy. Luminal contrast can be administered either orally or per rectum. Care is required in preparing the patient correctly; fasting or bowel laxative preparation may be required. Check local protocols for each study. GI radiology • Swallow: pharynx and oesophagus. • Meal: lower oesophagus, stomach, and duodenal cap. • Small bowel meal: small bowel, in particular the terminal ileum. • Single-contrast water soluble upper or lower GI study: to identify perforation or obstruction especially useful postoperatively. • Double-contrast enema: colonic pathology, excellent mucosal detail caution not in acute colitis or diverticulitis (perforation risk). • Biliary imaging, including endoscopic retrograde cholangiopancreatography (ERCP). • Procedures: nasogastric (NG) and nasojejunal (NJ) tube placement. Oesophageal and colonic stents. Uro radiology • Nephrostomy insertion. • Nephrostogram. • Ureteric stent insertion. • Cystogram, urethrogram. • Retrograde ureterograms (performed in theatre by urologists). • Loopograms or conduitograms (postoperative studies performed by retrograde administration of contrast into a neo-bladder after urinary diversions surgery to examine both the conduit and upper tracts).
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Fig. 1.2 Image from an upper GI contrast study, showing the double-contrast effect of the radio-opaque barium, against the radiolucent air. The stomach folds can be clearly seen in the distal stomach.
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Angiography Angiography is an imaging technique where a radio-opaque contrast agent is injected intravenously or intra-arterially and the target vessel is visualized using fluoroscopy. The image thus acquired is called an angiogram. Visceral, peripheral, and central arteries and veins can be imaged depending on the indication (Fig. 1.3).
Indications Angiography can identify: • Site of vascular stenosis or occlusion. • Vascular anatomy or anomalies prior to intervention or surgery. • Active bleeding. • Arterial dissection. • Graft and transplant angiography.
Procedure Access The common femoral vein or artery is most commonly used. The brachial route is an alternative, used when the femoral approach is either inappropriate (e.g. demonstration of upper limb venous anatomy prior to fistula formation) or unavailable. Rarely, direct puncture of a graft site may be performed. Jugular or subclavian vein puncture may also be performed, if the superior (SVC) or inferior vena cava (IVC) needs to be visualized. Local preparation The site is cleaned and under strict asepsis the appropriate vessel is targeted after administering local anaesthesia. Technique The choice of proper equipment prior to beginning the procedure is vital to its success. The vessel may be punctured using anatomical landmarks, but in some cases either ultrasound or fluoroscopic guidance is needed. Once the vessel is punctured, a guidewire is passed and its position confirmed with fluoroscopy. An appropriate vascular catheter is passed over the guidewire, which is then removed. Contrast is then either hand injected (if a small peripheral artery or vein is to be visualized) or pump injected (if aorta or IVC is to be visualized) and the anatomy is demonstrated. If necessary the appropriate vascular bed may then be selectively catheterized using special catheters or micro-catheters. Once the diagnostic images are acquired, these can then be transferred to an adjacent screen to be used as a road map for further intervention. Contrast agents The commonest agents are iodine-based compounds of different types. Hyperosmolar and ionic agents are not commonly used today, as iso-osmolar or hypo-osmolar non-ionic agents are preferred. Carbon dioxide is used as a negative contrast agent for angiography in patients with iodine allergy or renal failure. Gadolinium is also an alternative to iodinated agents.
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Complications • Puncture site complications: haematoma, pseudo-aneurysm, arteriovenous (AV) fistula and infection. • Contrast allergy and anaphylaxis. • Trauma to the vessel, leading to dissection, rupture, bleeding, or occlusion.
Alternatives to conventional angiography With the development of both CT and MR, the diagnostic role of invasive angiography is diminishing. Contrast-enhanced CT angiography and both contrast enhanced and unenhanced MR (such as time of flight and phase contrast MR) can be used to visualize different vascular beds for diagnostic purposes. These can then be used to guide conventional angiographic intervention.
Useful information for the radiologist It is important to know about the patient’s renal function, clotting profile, and any major underlying morbidity as often these patients need to lie flat for long periods of time. Prior imaging and background clinical history may provide useful information of the exact vascular bed to be imaged.
Fig. 1.3 Coronal image from an angiography study in a patient with peripheral vascular disease who presented with an acutely ischaemic left leg. The angiogram shows an occluded left iliac system, and heavily calcified right iliac arteries.
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Ultrasound Ultrasound imaging (Fig. 1.4) uses high-frequency sound waves (1–20MHz) and the way they travel through tissues, to image different areas of the body. Tissues of different densities reflect the sound waves back to the probe with their own characteristics. These variances are used to generate an image. • Ultrasoundwaves are reflected by bone and gas. It is therefore poor for imaging these bodily tissues and structures containing gas. • It is an operator-dependant form of imaging that is the first line of investigation in biliary, cardiac, renal, obstetric, and many vascular diseases. • It is frequently used to perform guided aspiration, biopsies, and insertion of drains (thoracic or abdomino-pelvic). • The use of Doppler ultrasound allows assessment of patency and flow in blood vessels.
Abdominal scan This investigation involves the evaluation of the solid organs of the abdomen (liver, gallbladder, pancreas, aorta, kidneys, spleen). It is used to assess: • Liver size and texture, assessment of any potential masses. • Biliary system: biliary duct dilatation, presence of stones, and gallbladder wall thickness. • Doppler of hepatic artery/veins and portal vein for flow characteristics. • Pancreas. • Aorta: assessing diameter for presence of an aneurysm. • Kidneys: for size, texture, presence of calculi and size of collecting system (i.e. looking for hydronephrosis). The bladder is not routinely examined in an abdominal ultrasound scan, therefore a dedicated renal examination should be requested if this is required. • Spleen: size and texture.
Urinary tract scan Assessment of kidneys (Fig. 1.5) and bladder: • Examination is performed with a full bladder to assess the bladder wall thickness accurately. • Pre- and post-micturition imaging can be obtained to gain information about the bladder capacity and emptying.
Pelvic scan Assessment of the uterus, ovaries, and pregnancy. Scans can be performed: • Transabdominally (TA): patient must have a full bladder. • Transvaginally (TV): this gives a more detailed assessment of the gynaecological organs.
Testicular scan This is used to assess testicular masses such as: • Tumours. • Hydrocoeles. • Inflammation/infection.
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Neck Ultrasound is used to assess: • Neck and thyroid masses. • Presence and characteristics of lymph nodes.
Cardiac ultrasound Measurement of chamber size. Accurate assessment of valve and wall motion: • 2D echocardiography provides real-time images of the anatomy and spatial relationships. • Duplex Doppler includes colour coding of flow directions and allows direct visualization of shunts and regurgitant flow.
Vascular scan Assessment of: • Carotid artery disease. • Peripheral vasculature. • Venous imaging.
Fig. 1.4 Longitudinal scan of the shoulder rotator cuff in a patient with restricted shoulder movements. The arrow points to the supraspinatus tendon and the arrowhead to the thickened subacromial bursa consistent with subacromial bursitis.
(a)
(b)
Fig. 1.5 a) Longitudinal image of a kidney with a dilated collecting system consistent with hydronephrosis. b) Longitudinal image of the common carotid artery with crosses outlining the tunica intima.
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Computed tomography Computed tomography (CT) uses X-rays to produce cross-sectional images of the body (Fig. 1.6). Images are generated by rotation of an X-ray tube around the patient. A ring of detectors located around the patient then measures the transmitted radiation. The numerical data obtained is computer processed to reconstruct the final images. In spiral or helical scanners the X-ray tube rotates continuously around the patient whilst the table, on which the patient is lying, is mechanically moved through the X-ray beam. This allows a continuous volume of data to be obtained rather than acquiring data one slice at a time. All modern CT scanners utilize spiral scanning and incorporate multiple rows of detector rings (known as multislice or multidetector scanners). Multidetector spiral CT has a number of advantages over single slice scanning: • Faster scanning: a greater area of the patient can be covered in a given time by the X-ray beam. • Better dynamic imaging: as a consequence of faster scanning, it is possible to acquire images during different phases of passage of contrast through tissues of interest. • Thinner slices: thin slices, down to sub-millimetre thickness, can be acquired thereby improving spatial resolution. • Genuine 3D imaging: this requires thin slices with equal x/y/z dimensions. This allows the volume of data to be reformatted in various planes (axial, sagittal, coronal, oblique) and as 3D representations of structures.
CT image reconstruction Every CT slice is subdivided into a matrix of up to 1024 x 1024 volume elements (voxels). Each voxel has been traversed during the scan by numerous X-ray photos and the intensity of the transmitted radiation measured by detectors. From these intensity readings, the density or attenuation value of the tissue at each point in the slice can be calculated. The viewed image is then reconstructed as a corresponding matrix of picture elements (pixels).
Hounsfield unit or CT number Each pixel is assigned a numerical value, which is the average of all the attenuation values contained within the corresponding voxel. This number is compared to the attenuation value of water and displayed on a scale of arbitrary units known as the Hounsfield unit (HU) or CT number (named after Sir Godfrey Hounsfield who developed the first CT scanner in 1972). This scale assigns water an attenuation value of zero HU. The range of CT numbers is usually 2000HU. Each number represents a shade of grey with +1000 (white) and −1000 (black) at either end of the spectrum.
Window level and window width The range of CT numbers recognized by the computer is 2000, but the human eye can only distinguish 11 different shades of grey. Hence, in order to be able to interpret the image, only a limited number of HU are displayed. This is achieved by setting the window level and window width on the computer to a suitable range of HU, depending on the tissue being studied.
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The term window level represents the central HU of all the numbers within the window width. The window width covers the HU of all the tissues of interest, which are displayed as various shades of grey. Tissues with HU outside this range are displayed as either black or white.
Contrast media Contrast between the tissues of the body can be improved by the use of contrast agents. These are usually substances with high molecular weight, which increase the attenuation value of tissues they opacify. Oral contrast This is used to opacify bowel thereby making it easier to identify pathology. Iodine-based preparations are usually used and are normally given to the patient to drink 1 hour prior to the examination. Intravenous contrast Iodine-based preparations are usually used to opacify the vascular tree. Different phases of enhancement can be obtained, depending on the timing of image acquisition. IV contrast is used to differentiate normal blood vessels from abnormal masses and to demonstrate the vascular nature of an abnormality.
Drawbacks of CT These include the use of ionizing radiation (doses vary according to the type of examination but can be high), hazards of IV contrast (renal impairment, allergy), lack of portability, and relative cost. Some areas of the body are imaged poorly with CT, including the posterior cranial fossa and spine.
Fig. 1.6 Axial CT image showing normal upper abdominal anatomy.
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Nuclear medicine (traditional) Description Nuclear medicine differs from other forms of imaging in that it shows the physiological function of a system rather than an anatomical region. Radioactive isotopes permit detection by emitting gamma radiation (G) which is detected by a gamma camera. In most cases the radioisotope is coupled to a biologically active molecule or drug to localize to a desired system. Pathological conditions may lead to increased uptake, i.e. hotspots or decreased activity, i.e. cold spots.
Radionuclides and radiopharmaceuticals When a radioactive substance decays it may emit radiation in the form of alpha (A) and beta (B) particles and electromagnetic radiation in the form of gamma rays and X-rays. It is gamma rays, which penetrate the body allowing detection, which are exploited in nuclear medicine imaging. Radionuclides are selected which produce a high volume of gamma emissions without emitting harmful particulate radiation (i.e. A or B particles). The half-life needs to be only long enough for the intended use, usually a few hours. The radionuclide is manufactured artificially and degrades spontaneously. The commonest radionuclide in use is technetium 99m (Tc-99m). This decays to technetium 99 with the emission of a G ray of 140keV (kilo-electron volts) and has a half-life of 6 hours. When a radionuclide is coupled with a drug, it is called a radiopharmaceutical. The pharmaceutical is chosen to rapidly localize to the intended target without side effects. Certain radionuclides, e.g. I-123 and Ga-67, localize to the desired area without an attached pharmaceutical. The radiopharmaceutical is injected, ingested orally, or inhaled.
The gamma camera The gamma camera consists of a large sodium iodide crystal with thallium iodide as an activator. The gamma rays striking the camera are converted into light photons, which are multiplied and converted into small voltage pulses to record activity. Some scattered rays are absorbed by a collimator placed in front of the crystal and the pulse height analyser selects photons of a predetermined narrow spectrum. The whole field image is shown on a cathode ray tube, which can be photographed or captured as an electrical pulse for a digital image.
The image The patient must sit or lie still in front of the gamma camera until sufficient activity is recorded. Images are acquired in each desired plane, e.g. anterior, posterior, lateral, or oblique. The image may be static or multiple frames may be acquired over a period of time to create dynamic images.
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Fig. 1.7 Selected image from a technetium bone scan in a patient with prostate cancer. Multiple areas of increased radioisotope uptake are consistent with bony metastases.
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Indications There are multiple uses of nuclear medicine imaging. Some of the commonest types of imaging are listed here with common indications. • Bone scan: Tc-99m labelled MDP (methyl-di-phosphonate): • Infection. • Occult fracture. • Bone metastases (Fig. 1.7). • Myocardial perfusion scan: Tl-201 chloride. • Thyroid uptake scan: I-123. • Renal imaging: • Static imaging: Tc-99m DMSA (dimercaptosuccinic acid)—for split renal function, ?renal scars. • Dynamic imaging: Tc-99m DTPA (diethylene triamine pentaacetic acid) or Tc-99m MAG 3 (mercaptoacetyltriglycine)—renal excretion, renovascular hypertension. • Ventilation/perfusion scan (V/Q scan): inhaled gas, e.g. Kr-81m or Tc-99m DTPA and injected Tc-99m albumin macroaggregates: • Pulmonary embolus exclusion (Fig. 1.8).
Contraindications The radiation dose of each scan must be weighed up against the alternative imaging techniques available. Particular care is needed with children, pregnant women, and breastfeeding mothers.
Advantages • Demonstrates physiology. • Widely available. • Relatively cheap.
Disadvantages • Radiation dose. Patient continues to emit radiation after procedure, in diminishing doses. • Poor spatial resolution for anatomical localization. • Time-consuming.
Dose The administered dose is measured in becquerels (usually in kilo- or megabecquerels). The effective patient dose is given in millisievert (mSv). The effective dose of a nuclear medicine scan varies with type and administered does of radiopharmaceutical. The effective dose of a typical Tc-99m MDP bone scan is 3mSv (compared to chest radiograph = 0.1mSv, average annual background radiation UK = 2.6mSv).
Patient preparation Certain types of nuclear medicine scan require patient preparation in terms of fasting, stopping medication, or taking medication prior to the examination. It is worth checking local policy with your nuclear medicine scan team when requesting an investigation for your patient.
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Fig. 1.8 Selected images from a V/Q scan, looking for a pulmonary embolus. Matched ventilation (upper row) and perfusion (lower row) in a normal scan.
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Techniques
PET-CT PET-CT is a relatively new technique, rapidly developing a central role in many imaging pathways. It involves the fusion of images from two very different imaging modalities—positron emission tomography (PET) and computed tomography (CT). The patient undergoes both scans sequentially, in the same session, and the results are merged, giving a combination of functional information from the radioisotope PET scan and the accurate anatomical detail of CT (Figs. 1.9 and 1.10).
Technique A short-lived radioactive tracer isotope—2–18 fluorodeoxy-D-glucose (FDG)—is injected intravenously. This radioisotope undergoes a process known as beta-decay, emitting a positron, which when it collides with an electron produces a pair of gamma photons that are subsequently detected within a gamma camera. FDG is a glucose analogue that accumulates within areas of high intracellular metabolism and glycolysis. Tumour cells are highly metabolically active, and also retain FDG more than do normal cells, meaning that the isotope becomes concentrated within the tumour resulting in a ‘hot spot’ on the image. FDG is not cancer specific, however, and is taken up in all areas of high metabolic activity, such as the brain, as well as by areas of inflammation or increased muscle activity.
Patient preparation • • • •
The patient is fasted for at least 4–6 hours prior to the scan. Plasma glucose levels should be checked before scanning. An IV injection of FDG is administered. The patient rests quietly for a period while the isotope circulates. Movement and talking are discouraged to prevent muscle uptake. • Scanning begins approximately 60 minutes following the injection and the total scan time is approx. 30–90 minutes. • Images are acquired from the top of the head to mid thighs, with the patient’s arms above their head. Usually the CT is obtained first followed by the gamma camera images. Because the scanners are in the same gantry the patient remains on a single scanning table and in the same position during both scans.
Indications • In general, PET is better than conventional imaging at demonstrating distant metastases from a wide variety of tumours. It is therefore used to complete the staging in cases where more traditional tests have suggested localized disease; e.g. in lung cancer, PET has been shown to upstage a significant proportion of patients thought on CT to be potentially operable. • PET is being used to provide early assessment of tumour response to chemotherapy allowing regimens to be altered if appropriate. • Also useful in early assessment of suspected disease recurrence in areas of post-treatment scarring or fibrosis. • Research roles in assessing myocardial perfusion. • Developing roles in neuro imaging.
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Relative contraindications • Pregnancy (high-dose examination, around 20mSv). • Uncontrolled diabetes makes interpretation difficult. • Patients must be able to lie still for considerable length of time.
Fig. 1.9 Coronal image from staging PET-CT showing increased uptake of oesophageal tumour (calliper).
Fig. 1.10 Image from a staging PET scan in a patient with lung cancer. Second incidental focus found within the left flank, found to be an incidental colonic tumour. The other areas of increased uptake are physiological.
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CHAPTER 1
Techniques
Magnetic resonance imaging General principles Materials placed in a magnetic field can absorb and then re-emit electromagnetic radiation of a specific frequency, usually in the form of radiosignals. When tissue is placed in a magnetic field (MRI scanner) the protons (hydrogen nuclei) align with the field. A radiofrequency electromagnetic field is then briefly turned on, causing the protons to alter their alignment relative to the field. When this field is turned off the protons return to the original magnetization alignment. These alignment changes create a signal which can be detected by the scanner. The frequency at which the protons resonate depends on the strength of the magnetic field. The position of protons in the body can be determined by applying additional magnetic fields during the scan, which allows an image of the body to be built up. These are created by turning gradient coils on and off which creates the knocking sounds heard during an MR scan. Protons in different tissues return to their equilibrium state at different rates. By changing the parameters on the scanner, this effect is used to create contrast between different types of body tissue. Various sequences can be achieved by changing imaging parameters. Basic sequences are T1, T2, T2*, proton density, inversion recovery (short tau inversion recovery, STIR (Fig. 1.11); fluid attenuation inversion recovery, FLAIR). More specialized sequences include diffusion-weighted imaging (DWI), MR angiography and functional imaging. The most widely used MR contrast agents are gadolinium chelates. Gadolinium is a paramagnetic substance that enhances the relaxation rate of surrounding tissue thereby producing greater T1 signal i.e. ‘bright’ on T1 imaging.
Applications MRI is used to image every part of the body, and is particularly useful for neurological conditions, disorders of the muscles and joints, tumours, and for showing abnormalities in the heart and blood vessels. While CT offers greater spatial resolution (ability to distinguish two structures a small distance apart as separate structures) MRI offers greater contrast resolution (ability to distinguish two similar, but not identical tissues). MRI does not use ionizing radiation and there are as yet no reported long-term biological effects from prolonged exposure to a magnetic field. This makes MRI more appropriate in children and pregnancy. There are disadvantages to MRI. Acquiring images is time consuming and scans can often last 20–40 minutes. Patients must be able to lie still for this length of time. Young children will often require a general anaesthetic. Patients with claustrophobia may not tolerate MRI and sedation or alternative imaging may be required.
Contraindications There are absolute contraindications: • Cardiac pacemakers. • Cochlear implants. • Tissue expanders. • Ocular prostheses.
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• • • • •
19
Dental implants. Neurostimulators. Bone growth stimulators. Implantable cardiac defibrillators. Implantable drug infusion pumps.
New medical devices tend to be MRI compatible and MRI safe pacemakers are now available. Others to consider are orthopaedic implants/metalwork, vascular clips, intravascular coils and bullets/pellets/shrapnel. Most of these are safe, but they should be evaluated on a patient-by-patient basis. More information is freely available online (http://www.mrisafety.com).
Fig. 1.11 Sagittal STIR image of the cervical spine showing intra-cord abscess and oedema secondary to tuberculosis.
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CHAPTER 1
Techniques
Interventional radiology Radiological interventional techniques use image guidance such as fluoroscopy, ultrasound, or CT to help in a diagnostic or therapeutic procedure. The role of interventional radiology is continually expanding and there is hardly any area of hospital medicine where it does not have an impact on patient management. The advantages include reduced risk as compared to surgery, shorter hospital stay, lower cost, greater comfort, quicker convalescence, and return to work.
Non-vascular intervention Includes diagnostic biopsies, drainage of collections, GI procedures such as oesophageal, gastroduodenal and colonic stent placement, percutaneous gastrostomy and gastrojejunostomy insertions, biliary drainage, urological procedures such as percutaneous nephrostomy and antegrade ureteric stent placement, etc.
Vascular intervention Includes procedures such as angiography (Fig. 1.12), angioplasty, stent placement, thrombolysis, EVAR (endovascular aneurysm repair), tumour embolization, uterine fibroid embolization, postpartum haemorrhage management, bronchial artery embolization, Hickman line insertions, Varicocoele embolization, IVC filter placement and retrieval, etc.
Pre-procedure preparation • • • • • •
Confirm the clinical indication. Check previous imaging. Check the coagulation and infection screen as per local protocols. Consider use of medication such as sedatives, analgesics, etc. Choose the correct imaging modality for the procedure. Obtain informed consent.
Ultrasound-guided procedures Ultrasound is used for various biopsy and drainage procedures. It is ideal if the target is clearly visible and a suitable approach is possible. The advantages of using ultrasound are that procedure is performed in real time, it can be done portably in ICU etc, and does not involve ionizing radiation. The procedure can be performed using a needle guide attached to the ultrasound probe, which shows the path the needle will take. Another method is to use a freehand technique wherein the probe is fixed with one hand and the needle is advanced into the target with the other. The latter technique is more difficult and requires expertise.
CT-guided intervention When it is not possible to access the target using ultrasound guidance (e.g. pathology within lung, related to bowel, etc.), CT guidance may be used. The puncture site is marked following a reference scan. Needle path to the target is planned. After each needle pass, the patient goes into the scanner and is then brought out again making the procedure more ‘stop/ start’ and time consuming than when using US. Once the needle is in a satisfactory position, the appropriate procedure is performed.
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Aftercare This varies with the type of procedure, the general condition of patient, the coagulation status, etc. Depending on local protocols the procedure may be performed as a daycase and all aftercare takes place in the radiology department, or the patient may be returned to a ward in which case a written aftercare plan should go with them. It should always be mentioned if the procedure was difficult or if there were any immediate complications.
Complications These vary with the type and site of procedure, and between individual patients. Serious complications are rare. Following are some of the important complications to look out for: • Bleeding. • Infection. • Bowel perforation. • Pneumothorax. Most complications can be managed adequately but need to be thought about and recognized early.
Useful information for the radiologist Detailed clinical history and clinical differential diagnosis, coagulation status, and infection screen. If the patient is uncooperative or extremely anxious then may need to consider pre-medications or sedation.
Fig. 1.12 Image from a vascular angiography study in a patient who has undergone endovascular repair of their abdominal aortic aneurysm. The stents can be clearly seen.
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Chapter 2
Respiratory differential diagnosis Focal consolidation 24 Widespread consolidation 24 White out 24 Solitary lung mass 24 Multiple lung masses 25 Pleural effusion 25 Cardiomegaly 25 Unilateral hyperradiancy 25 Bilateral hyperradiancy 25 Upper zone fibrosis 26 Small fibrotic lungs 26 Kerley B lines 26 Bilateral hilar enlargement 26 Unilateral hilar enlargement 26
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Respiratory differential diagnosis
Focal consolidation • • • • • •
Pneumonia. Haemorrhage. Contusion. Alveolar cell carcinoma. Cryptogenic organizing pneumonia. Lymphoma.
Widespread consolidation • • • •
• • • •
Infection. Oedema. Pulmonary haemorrhage. Tumour: • BAC. • Lymphoma. • Widespread metastases. Proteinosis. Alveolitis. Cryptogenic organizing pneumonia. Eosinophilic pneumonia.
White out • Mediastinum shifted toward white out: • Collapsed lung. • Pneumonectomy. • Mediastinum shifted away from white out: • Pleural fluid. • Large mass. • Mediastinum central: • Combination of collapse and fluid. • Widespread consolidation. • Pleural tumour.
Solitary lung mass • • • • • • • • •
Primary lung cancer. Solitary metastasis. Lymphoma. Benign tumour: • Carcinoid. • Hamartoma. Arteriovenous malformation (AVM). Post-infective scar/granuloma. Round pneumonia. Rheumatoid nodule (usually multiple). Infarct.
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Multiple lung masses • • • • • •
Multiple metastases. Vasculitis. Rheumatoid nodules. Multiple emboli. Multi focal infection. Progressive massive fibrosis (PMF).
Pleural effusion • Large, unilateral. • Mesothelioma. • Metastatic pleural tumour. • Empyema. • Small/moderate, unilateral: • Parapneumonic (associated with consolidation). • Empyema. • Malignancy (as above). • Bilateral: • Heart failure. • Fluid overload. • Hypoalbuminaemia.
Cardiomegaly • LV failure. • Pericardial effusion.
Unilateral hyperradiancy • Rotation of the patient. • Pneumothorax. • Chest wall abnormality: • Mastectomy. • Poland’s syndrome.
Bilateral hyperradiancy • Bilateral pneumothorax. • Over expanded lungs: • Chronic obstructive pulmonary disease (COPD). • Asthma.
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CHAPTER 2
Respiratory differential diagnosis
Upper zone fibrosis • • • • • •
Sarcoid. Tuberculosis (TB). Post radiation. Pneumoconiosis. Extrinsic allergic alveolitis (EAA; chronic). Ankylosing spondylitis.
Small fibrotic lungs • • • •
Idiopathic pulmonary fibrosis. Drug-induced fibrosis. Asbestosis. Connective tissue disease.
Kerley B lines • Heart failure. • Lymphangitis. • Sarcoid.
Bilateral hilar enlargement • Sarcoid. • Pulmonary hypertension. • Lymphoma.
Unilateral hilar enlargement • Lung cancer. • TB. • Infection.
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Chapter 3
Respiratory presenting syndromes Chest pain 28 Wheeze 30 Shortness of breath 32 Cough 34 Haemoptysis 36 Hypoxia 38
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CHAPTER 3
Respiratory presenting syndromes
Chest pain This symptom is associated with a variety of disease processes, many of which are common and potentially life threatening. A possible myocardial infarction must be the first consideration in all adults with acute chest pain. Once this has been excluded, the list of differential diagnoses can be narrowed by accurate interpretation of history, examination, and investigations (Table 3.1).
Investigations These will be guided by the presentation and likely diagnosis. In general, an electrocardiogram (ECG) is required to rule out cardiac ischaemia/infarction as well as a plain chest radiograph. A summary of available imaging tests relevant in the investigation of chest pain are briefly described in the ‘Imaging’ section. More detailed applications and findings will be discussed under each relevant condition.
Imaging Plain chest radiograph This may prove to be diagnostic. It may show signs of cardiac failure, pneumothorax, or collapse/consolidation. Mediastinal widening, shift, and the presence of free gas can all be detected. Ultrasound Ultrasound examination of the heart (echocardiography) can be used to detect aortic arch aneurysms, dissecting aneurysms, cardiomayopathy and pericardial effusion. Transoesophageal echocardiography (TOE) has been developed to overcome limitations of conventional echocardiography in trying to image through the anterior chest wall. Ultrasound examination of the chest can be used to detect the presence of pleural fluid and to guide aspiration/drainage. CT Can be used to evaluate/diagnose dissecting thoracic aneurysms, pericardial effusions, and myocardial tumours. More advanced scanners allow non-invasive assessment of the coronary arteries. Recent NICE guidelines recommend unenhanced CT to assess coronary artery calcification in cases of atypical chest pain. Respiratory causes of chest pain can be evaluated with CT, including CT pulmonary angiography (CTPA) for suspected cases of pulmonary embolism. CT also allows evaluation of the pleural space and chest wall. Nuclear medicine Thallium (201TI) exercise test Not used in the acute setting but can differentiate viable from non-viable myocardium and hence identify those patients who would benefit from coronary revascularization. Following injection with 201TI, imaging is performed immediately after exercise and then repeated 4 hours later.
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Ventilation/perfusion imaging Combined perfusion scanning with technetium-99m-labelled macroaggregates of human albumin and ventilation scanning with inhaled radioactive gas or aerosol to assess possible pulmonary embolus. MRI Little role in acute setting. Has some value in assessing pericardial effusions, hypertrophic cardiomyopathy, and congenital/valvular heart disease. MR angiography provides a non-invasive method of imaging vascular abnormalities such as aneurysm and dissection, but does not have the spatial resolution necessary to assess the coronary arteries. Arteriography Coronary angiography This is a commonly performed examination during which contrast is initially injected into the left ventricle to evaluate function, and subsequently into the coronary arteries to demonstrate the extent of any stenoses or occlusion. Angioplasty and stenting can then be performed if indicated. Pulmonary angiography This is an invasive procedure which is now rarely performed since the advent of CTPA. It involves selective catheterization of the pulmonary artery (either through the jugular or femoral vein) and contrast injection to visualize the pulmonary circulation. Table 3.1 Differential diagnosis Cardiac
Pulmonary
Other
Myocardial ischaemia/ infarction*
Pneumothorax*
Oesophageal rupture with mediastinitis*
Aortic dissection*
Pulmonary embolus*
Pancreatitis*
Pericarditis
Pneumonia
Oesophagitis
Myocarditis
Lung cancer
Cholecystitis
Mitral valve prolapse
Mesothelioma
Herpes zoster (shingles)
Pleural effusion
Costochondritis (Tietze’s disease) Vertebral collapse Trauma
* Potentially
rapidly life threatening
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Respiratory presenting syndromes
Wheeze Wheeze is the sound produced by the vibration of narrowed airways. Normally heard best in expiration, wheeze can be either polyphonic, with multiple different pitches and volumes, or monophonic with a single constant pitch. Wheeze which can only be heard in inspiration is termed stridor and is indicative of an upper respiratory tract cause. A localized or fixed wheeze is suspicious of tumour or foreign body within an airway.
Polyphonic wheeze • • • • • • •
Asthma. COPD. Cardiac failure. Anaphylaxis. Extrinsic allergic alveolitis (EAA). Chondromalacia. Pneumonia (less common).
Monophonic wheeze • Bronchial carcinoma. • Foreign body.
Stridor • • • • • • • • •
Anaphylaxis. Peritonsilar or retropharyngeal abscess. Epiglottitis/croup. Foreign body. Pharyngeal pouch. Thyroid goitre. Upper respiratory tract neoplasm. Vocal cord paralysis. Rarely congenital vascular abnormalities/rings in children.
Imaging In acute life-threatening airway obstruction imaging is a distraction. The patient requires urgent clinical management. Once the patient is stabilized imaging may play a role. Plain film • Chest x-ray (CXR) can identify tumour, foreign bodies, cardiac failure, or infection. • Background conditions such as COPD may be evident. • In acute asthma the CXR may be normal or show only large volume lungs, but is useful to exclude pneumothorax or exacerbating conditions such as infection. • A lateral cervical spine x-ray may identify radio-opaque foreign bodies or rarely a fluid level in a retropharyngeal abscess.
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CT • CT of neck and chest may reveal extrinsic airway compression by mass lesions, endoluminal lesions within the airways, or congenital abnormalities. • Expiratory CT can demonstrate focal areas of air trapping in patients with small airways disease and collapse of the larger airways in those with bronchomalacia. Ultrasound Ultrasound is not routinely used to investigate wheeze. Neck masses such as nodes or goitre can be assessed. Fluoroscopy /nuclear medicine/MRI These are not routinely used. However a barium swallow will diagnose a pharyngeal pouch or identify extrinsic oesophageal compression which may indicate pathology such as vascular rings that are also causing airway compression.
Information for the radiologist • • • • • •
Any history of background lung conditions. Has a foreign body been inhaled (some are not radio-opaque)? Location of the wheeze. Any history of smoking, cancer, or congenital abnormality. Respiratory function tests. Is there a seasonal picture or anything to suggest allergy?
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Respiratory presenting syndromes
Shortness of breath A common problem with a wide range of causes. The key to narrowing the differential diagnosis lies in accurate history taking and examination.
Presentation Presentation varies according to the cause. Associated symptoms should be elicited. The duration of illness is helpful to narrow the differential diagnosis: • Sudden onset (over minutes): • Pneumothorax: pleuritic chest pain. May be a history of trauma. • Myocardial infarction: chest pain, sweating, clammy. • Pulmonary embolus: pleuritic chest pain, haemoptysis, syncope. • Inhaled foreign body: often in children, cyanosis, stridor. • Anaphylaxis: stridor, tongue/throat swelling, urticarial rash. • Acute (onset over hours): • Asthma: expiratory wheeze, chest pain. • Pneumonia: fever, productive cough, coarse crepitations. • Pulmonary oedema: widespread inspiratory crepitations. • Cardiac tamponade: muffled heart sounds, raised jugular venous pressure (JVP), hypotension. • Metabolic acidosis: e.g. diabetic ketoacidosis. Check glucose, arterial blood gases (ABG). • Inappropriate hyperventilation. • Chronic (onset over months): • Asthma. • COPD: history of smoking, wheeze and recurrent chest infections. • Interstitial lung disease: e.g. idiopathic pulmonary fibrosis. • Heart failure: worse on exertion, orthopnoea, peripheral oedema. • Pulmonary hypertension: chest pain, fatigue, right heart failure. • Lung cancer: weight loss, cough, haemoptysis, smoking history. • Anaemia: pallor. Check full blood count (FBC). Adjuncts to clinical examination include ECG, ABG, routine blood tests, and pulse oximetry.
Imaging Plain film CXR is the initial imaging investigation. It may identify many of the acute causes, e.g. pneumothorax, pleural effusion, cardiac failure, pneumonia. Also useful to compare with old radiographs in cases of chronic dyspnoea. CT Occasionally required if the diagnosis cannot be made on plain film. Performed as high resolution CT (HRCT), CTPA, or normal contrast enhanced CT depending on the clinical question. Nuclear medicine V/Q scans are used to identify pulmonary emboli.
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Ultrasound May demonstrate pleural or pericardial effusions.
Information for the radiologist • Presenting symptoms and duration of illness. • Relevant past medical history, e.g. cardiac disease, smoking, allergy. • Clinical differential diagnosis.
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Respiratory presenting syndromes
Cough Cough is a common presenting complaint and there are a wide range of causes, of which upper respiratory tract infection is the most common.
Presentation Presentation varies according to the cause. The nature of the cough should be explored: • Duration: acute or chronic (see later in topic). • Productivity: dry, sputum, blood. • Timing: e.g. worse in early morning (asthma), following food (reflux). • Environmental precipitants: e.g. drugs, pets, smoking, exercise. Associated symptoms may include nasal discharge, fever, wheeze, dyspnoea, peripheral oedema, weight loss, or recurrent chest infections and provide important clues as to the underlying aetiology. The duration of symptoms can be used to classify causes: • Acute (3 weeks): • Post-nasal drip. • Airway disease: COPD, asthma, lung cancer, bronchiectasis. • Interstitial lung disease. • Extrinsic allergic alveolitis. • Heart failure. • Gastro-oesophageal reflux disease with recurrent aspiration. • Drugs: e.g. angiotensin converting enzyme (ACE) inhibitors.
Imaging Plain film Recommended if symptoms last 3 weeks or more. A good screening tool if there is concern for a pulmonary or cardiac cause. CT Persistent cough is sometimes investigated with CT, particularly if there is concern for malignancy, bronchiectasis, or interstitial lung disease. Ultrasound Echocardiography is a reliable method of assessing cardiac function. Fluoroscopy Contrast swallow examinations can demonstrate gastro-oesophageal reflux and aspiration.
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Information for the radiologist • Nature of cough and associated symptoms. • Relevant environmental history e.g. pets, occupational history, smoking.
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Respiratory presenting syndromes
Haemoptysis Haemoptysis is the coughing up of blood from the lungs or tracheobronchial tree (Table 3.2). Massive haemoptysis refers to the coughing up of >200ml of blood in 24 hours.
Imaging The cause of haemoptysis may be obvious from the history and investigations should be performed according to the likely diagnosis. Plain film This should be performed in all patients presenting with haemoptysis. It may reveal a mass lesion, mediastinal lymphadenopathy, bronchiectasis, cavitation, consolidation, or pulmonary oedema. Ultrasound Ultrasound examination of the heart (echocardiography) can be used to detect cardiac causes of haemoptysis including anatomical abnormalities, valvular disease, and ventricular dysfunction. CT CT of the chest may identify parenchymal or endobronchial lesions, or further characterize abnormalities seen on plain chest radiograph. HRCT is performed where generalized lung disease is suspected (e.g. bronchiectasis). Traditional intermittent HRCT uses widely spaced, thin sections and is therefore unsuitable for the assessment of lung cancer or other localized lung diseases. Similarly, IV contrast agents are not routinely administered making the technique unsuitable for assessment of soft tissues and blood vessels. CTPA is commonly performed for suspected pulmonary embolism. In this test, iodinated contrast is administered intravenously to opacify the pulmonary arterial tree. Any filling defects indicate the presence of a pulmonary embolus. In cases of massive haemoptysis contrast enhanced CT can be useful in identifying enlarged bronchial arteries which may be suitable for embolization. Nuclear medicine V/Q imaging should be considered for patients with suspected pulmonary embolism who have a normal chest radiograph and no known history of respiratory disease. Combined perfusion scanning with technetium99m-labelled macroaggregates of human albumin and ventilation scanning with inhaled radioactive gas or aerosol typically produces a perfusion defect and not a ventilation defect in pulmonary embolus. MRI The lungs are not well visualized with MR and its use in the assessment of respiratory causes of haemoptysis is limited.
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Angiography Pulmonary angiography can identify the bleeding source in 90% of patients with massive haemoptysis and can be combined with embolization of the bleeding vessel. Other Fibreoptic bronchoscopy may be used in cases of suspected malignancy. It is diagnostic for central endobronchial lesions and allows direct visualization of the bleeding site. In cases of more peripheral bleeding the bronchoscopist may be able to identify the affected lobe, which is useful information for a vascular radiologist considering embolization. It also permits tissue biopsy, bronchial lavage, or brushings for pathological diagnosis. Table 3.2 Differential diagnosis Pulmonary
Cardiac
Systemic vasculitis
Bronchiectasis
Pulmonary embolus
Systemic lupus erythematosus (SLE)
Bronchogenic carcinoma
Left ventricular failure
Wegener’s granulomatosis
Infection
Mitral stenosis
Goodpasture’s syndrome
TB
Pulmonary hypertension
Pneumonia
Aortic aneurysm (aorto-bronchial fistula)
Lung abscess Aspergilloma Trauma AV malformation
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Respiratory presenting syndromes
Hypoxia Hypoxia is defined as reduced oxygen supply to tissues despite adequate blood supply. Possible causes are listed:
1. Reduced oxygen carrying capacity • Anaemia. • Carbon monoxide poisoning. • Haemoglobinopathies (e.g. sickle cell, thalassaemia).
2. Reduced blood supply to lungs • • • • •
Pulmonary embolism (thrombus, fat, amniotic). Right-sided heart failure. Pulmonary hypertension. Pulmonary valve stenosis. Congenital heart disease.
3. Reduced diffusion of oxygen across the alveolar membrane • Upper airway obstruction (e.g. foreign body). • Lower airway pathology (e.g. asthma/COPD/tumour). • Material within alveoli: • Inflammatory cells (infection/hypersensitivity). • Pulmonary haemorrhage. • Pulmonary oedema. • Tumour. • Interstitial lung disease/fibrosis. • Bronchiectasis/cystic fibrosis. • Collapse of lung due to pneumothorax or pleural effusion. • Neuromuscular disorders (e.g. Guillain–Barré syndrome).
Imaging Plain film • A CXR is likely to be the first form of imaging used to investigate the hypoxic patient. It is most useful for the 3rd category of causes listed earlier. • Cardiac and mediastinal abnormalities may suggest a cause from the 2nd category. • Remember CXR signs may lag behind the clinical findings. CT • Standard CT thorax ± contrast provides detailed 3D information. • CTPA is the investigation of choice for detecting pulmonary emboli. • HRCT acquires 1mm slices to assess the structures of the small airways and interstitium. Used in the diagnosis of interstitial lung disease and atypical infection. • Cardiac CT assesses cardiac structure and function; however is usually performed after an echocardiogram.
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Ultrasound • Ultrasound can confirm pleural effusions or pneumothorax prior to guided intervention. • Echocardiography evaluates cardiac structure and function. Nuclear medicine V/Q scanning can be used to investigate pulmonary embolism if immediately available but should only be used in those patients with a normal CXR and no previous cardiorespiratory disease. MRI Cardiac MRI assesses structure and function of the heart but is usually a second-line examination.
Information for the radiologist • Relevant history including previous respiratory disease, smoking, immunosuppression, malignancy, or previous surgery. • A differential diagnosis is vital to choose the most appropriate investigation.
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Chapter 4
Respiratory conditions Lung abscess 42 Pneumonia 44 Emphysema/COPD 46 Pulmonary embolus 48 Left ventricular failure 52 Pneumothorax 54 Wegener’s granulomatosis 56 Pulmonary hypertension 58 Solitary pulmonary nodule 60 Lung cancer 62 Lobar collapse 64 Bronchiectasis 70 Cystic fibrosis 72 Pleural effusion 74 Interstitial lung disease 76 Connective tissue disease and the lung 78 Pneumoconiosis 80 Sarcoidosis 82 Benign asbestos-related disease 84 Tuberculosis 86 Malignant pleural disease 88 Mediastinal masses 90
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CHAPTER 4
Respiratory conditions
Lung abscess A lung abscess is a well-defined collection of pus, usually with a discrete wall and surrounded by inflamed lung tissue. They usually develop as a complication of bacterial pneumonia and may be solitary or multiple.
Clinical presentation The clinical course is often insidious, with fever, lethargy, and night sweats. Breathlessness and productive cough with haemoptysis may be present. • If due to aspiration, abscesses often involve the posterior segments of the upper lobes and the apical segments of the lower lobes, as these areas are gravity dependent when the patient is supine. • Systemic bacteraemia or tricuspid valve endocarditis can cause multiple septic emboli throughout the lungs leading to abscess formation. • Secondary abscess formation can occur within pre-existing cavities (bullae or lung cysts), or distal to an obstructed bronchus, e.g. secondary to a carcinoma or inhaled foreign body.
Imaging Plain film Chest radiographs may not be diagnostic in the early stages of abscess formation, often showing a non-specific area of consolidation, before progressing to the classical appearance of a well-defined mass with an airfluid level (Fig. 4.1). Remember, the air-fluid level will only be present on upright films. Ultrasound Limited role in imaging the abscess itself, but echo is useful if septic emboli from endocarditis considered. CT • Identifies cavitation within an area of consolidation. • Delineates the position of the abscess with respect to bronchial anatomy and the chest wall (Fig. 4.2). • Useful for differentiating between intrapulmonary abscess and loculated empyema. • Furthermore, CT is invaluable for accurate placement of drainage catheters, if required.
Information for the radiologist • Is the patient septic? • Is the patient at risk of aspiration or is there a history such as an alcoholism, immunosuppression, epilepsy, or dysphagia? • Before considering percutaneous drainage appropriate broad-spectrum antibiotics should usually have been given a suitable trial first. • If drainage is being requested lung function and INR will be required.
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Fig. 4.1 CXR of a 35-year-old man with fever and purulent cough showing a thin-walled abscess in the right lung apex containing an air fluid level.
Fig. 4.2 CT of same patient as Fig. 4.1 confirming the position and nature of the abscess in the right upper lobe with small amount of surrounding consolidation. Note the thin, smooth wall and air fluid level. (Patient grew Staph. aureus from blood cultures and abscess resolved with antibiotic treatment.)
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Respiratory conditions
Pneumonia Bacterial pneumonias are categorized by their infectious agents, which include Streptococcus pneumoniae (the most common cause of bacterial pneumonias), Haemophilus influenzae, Klebsiella, Staphylococcus, Legionella species, and Gram-negative organisms. Susceptibility to pneumonias increase with very young or old age, COPD, alcoholism, and immunocompromise.
Clinical presentation • Patients may present with cough productive of sputum (green or rust coloured), rigors, malaise, myalgia, dyspnoea, or pleuritic chest pain. • Legionella pneumonia is associated with GI symptoms including anorexia, nausea, vomiting, and diarrhoea. • Signs are legion, and include fever, wheeze, tachypnoea, tachycardia, dullness on percussion, decreased breath sounds, rhonchi and rales on auscultation, and a pleural friction rub.
Imaging Plain film (Fig. 4.3) CXR is the initial investigation in most cases and important in follow-up. • Lobar consolidation (ill defined opacity with air bronchograms). • Cavitating pneumonia and bulging of fissures is suggestive of Klebsiella, (which has a predilection for the upper lobes), Staphylococcus aureus or TB (see b Tuberculosis, p. 86). • Pleural effusion. • Abscess. • Lobar collapse. Ultrasound No role in uncomplicated pneumonia but useful to identify and localize secondary effusions/empyema. CT • Not needed in uncomplicated cases which resolve on treatment. • Useful in non-resolving infection to look for an obstructing lesion or atypical features such as cavitation.
Information for the radiologist • Duration of symptoms. • Bronchoscopy results if relevant. • Risk factors including immunosuppression.
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Fig. 4.3 CXR showing extensive consolidation throughout the left lung, due to proven streptococcal pneumonia.
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Emphysema/COPD Emphysema is defined as irreversible dilatation of the airways distal to the terminal bronchiole, accompanied by the destruction of alveolar walls and without obvious fibrosis. Frequently occurs in association with bronchitis and these entities are referred to with the collective term chronic obstructive pulmonary disease (COPD).
Clinical presentation Patients typically present in their 5th/6th decade with breathlessness and productive cough. Smoking is a common factor. Clinical signs • Hyperinflation, i.e. ‘barrel chest’. • Wheezing. • Hyperresonance on percussion.
Imaging Plain film (Figs. 4.4 and 4.5) • Increased lung volumes (increased AP diameter on lateral). • Flattened diaphragms. • Hyperlucency of lungs. • Reduction in number and calibre of vascular shadows. • Bullae (air spaces that measure >1cm in diameter). CT Emphysema is usually an incidental finding as CT is not used in the routine care of patients with COPD. CT is indicated in those patients who are undergoing evaluation for surgical intervention, i.e. bullectomy or lung volume reduction surgery. Typical findings include: • Extensive areas of low attenuation without definable walls. • Thin walled avascular areas (bullae). • Paucity of vascular markings in affected areas. • Upper lobe predominance in centrilobular and paraseptal emphysema. • Lower lobe predominance in panacinar emphysema (feature of alpha-1 antitrypsin deficiency). Nuclear medicine V/Q scanning is performed to assess relative lung function and distribution of disease prior to lung volume reduction surgery.
Information for the radiologist • Smoking history. • Duration of symptoms. • Respiratory function tests.
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Fig. 4.4 PA CXR showing bullous emphysema throughout most of the right upper lobe. Note the absence of lung markings in the right upper and mid zones and the depression of the horizontal fissure.
Fig. 4.5 PA CXR showing overexpanded lungs and flattening of the hemidiaphragms typical of COPD.
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Pulmonary embolus A pulmonary embolism (PE) is a blockage of the pulmonary artery, or its branches. This may be acute, most commonly a clot from a DVT, or chronic, due to longstanding thromboembolic disease. Other, less common causes include fat, tumour, air, and amniotic fluid emboli. The ideal imaging protocols for diagnosing PE remain a subject of debate amongst radiologists.
Clinical presentation Classically, patients present with pleuritic chest pain, breathlessness, a swollen leg, and ECG changes but PE may present with symptoms ranging from vague breathlessness to cardiac arrest. Risk factors include: • Recent immobilization. • Recent surgery. • Previous PE/DVT. • Smoking. • Pregnancy/oral contraceptive pill. • Thrombophilic disorders including malignancy.
Imaging features Plain film • Non-specific and up to 40% of patients with acute PE have a normal CXR. • Will quickly exclude other conditions which may mimic PE, including pneumothorax, pneumonia and aortic dissection, and is important in deciding which imaging modality will subsequently be used. Ultrasound As the treatment for above-knee DVT and PE is the same, ultrasound scanning and demonstration of a DVT mitigates the need for further investigation. Echocardiography • Assessment of right heart strain in acute PE (and may visualize large clot in central pulmonary arteries). • Right ventricular hypertrophy in chronic embolic disease. CTPA (Fig. 4.6) • Emboli are seen as intraluminal filling defects within the contrast enhanced pulmonary arteries. • When clot is seen the PPV is high, but these studies can be difficult to interpret, particularly in the context of respiratory motion artefact and poorly opacified pulmonary vessels. • CTPA has the advantage of providing additional information not possible with perfusion scanning, such as the presence of right heart strain and infarcted lung.
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Ventilation/perfusion scanning (Fig. 4.7) • Radioisotope assessment of ventilation (using inhaled agents such as Xe-133, Tc-99m aerosol) and lung perfusion (using a venous injection of Tc-99m macroaggregated albumin) is the traditional method of PE diagnosis and remains a commonly used test in many departments. • A high probability scan is very accurate in confirming the presence of PE, whilst a normal study excludes significant PE. • However, a significant proportion of the studies are indeterminate and further imaging is needed. • The chances of an indeterminate scan are much higher in those with an abnormal CXR, hence these patients are normally sent straight to CT. MRI • MRI of the pulmonary vasculature is possible; however, spatial and contrast resolution is inferior to CTPA, and MR in acute PE is rarely used. • In chronic embolic disease MRA combined with assessment of right ventricular function is commonly used in pre-treatment work-up. Pulmonary angiography Conventional pulmonary angiography is still nominally the gold standard for the diagnosis of PE. However, it is an interventional procedure (overall complication rate is 2–5%) and is now rarely performed outside of specialist centres.
Information for the radiologist • Pretest probability (including D-dimer). • Does the patient have asthma or chronic lung disease?
Fig. 4.6 Axial image from CTPA reveals filling defects in both main pulmonary arteries in keeping with pulmonary emboli.
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Fig. 4.7 Image from V/Q scan from a different patient than Fig. 4.6 demonstrating the normal appearance bilaterally. This pattern virtually excludes PE.
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Left ventricular failure Failure of the left ventricle to pump adequately, either as a consequence of systolic dysfunction (a reduction of myocardial contractility), diastolic dysfunction (an abnormality of distensibility), or a combination of the two.
Clinical presentation Worsening breathlessness, orthopnoea, basal crepitations, wheeze and respiratory failure may all indicate left ventricular failure (LVF). Onset may be acute or insidious. In patients with limited cardiac reserve, a separate episode such as a chest infection may precipitate acute LVF. LVF may develop following acute MI due to the loss of functioning myocardium, arrhythmias, papillary muscle rupture, ventricular septal defect (VSD), or transmural infarct resulting in haemopericardium.
Imaging Plain film The radiographic changes centre on cardiomegaly (cardiothoracic ratio >55%) and pulmonary oedema. As the pulmonary capillary wedge pressure (PCWP) rises, cephalization of the pulmonary vascularity (upper lobar venous diversion) develops. Interstitial oedema is the next sign, as evidenced by peribronchial cuffing, loss of clarity to vessels, fluid in the fissures, and development of interstitial lines: • Kerley A lines radiate out from the hila. • Kerley B lines: short horizontal lines in the lung peripheries (Fig. 4.8). Further rises in PCWP lead to the development of alveolar pulmonary oedema, seen as bilateral air-space shadowing and pleural effusions. In this phase, it may be radiologically impossible to differentiate heart failure from severe infection. Echocardiogram Features of LVF include poor ejection fraction (EF), poor wall motion and contractility, and enlarged left ventricular chamber volumes. Nuclear medicine Very limited role in the imaging in acute LVF. MRI • Limited role in the acute setting. • MRI is the most accurate modality for assessing LV function as well as myocardial reserve. It is also useful in assessing cardiomyopathy and the underlying cause. CT Limited role in the acute setting but can demonstrate causes such as acute VSD following infarction.
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Information for the radiologist • Any underlying cardiac condition which may be responsible for acute LVF should be mentioned. • One common question is differentiation between LVF and chest infection which can be difficult purely on plain films. • Clinical story and laboratory results will be needed to complete the picture.
Fig. 4.8 PA CXR revealing cardiomegaly, upper lobe venous distension, Kerley B lines, and thickened interstitial markings in keeping with interstitial oedema secondary to heart failure. Note also the left pleural effusion.
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Pneumothorax A pneumothorax occurs when air enters the pleural cavity, separating the visceral from the parietal pleura, with subsequent collapse of the underlying lung. The air can be free within the pleural cavity, loculated, or under tension, causing haemodynamic compromise and instability. Spontaneous pneumothoraces are more common in asthmatics, patients with emphysema, cystic fibrosis, and TB. There is also a predisposition to spontaneous pneumothorax in tall thin males (and those with Marfan’s syndrome). Traumatic pneumothorax is often the result of chest wall compression or penetrating injury with lung laceration. Remember iatrogenic causes, such as insertion of central venous lines, lung biopsies, radiotherapy, and positive pressure ventilation.
Clinical presentation Pneumothorax can present with sudden onset of chest pain and breathlessness, or, in the case of tension pneumothorax, with cardiovascular compromise and collapse. It is an important diagnosis to exclude in the context of trauma, where small pneumothoraces may go undetected on the supine CXR, resulting in rapid decompensation should positive pressure ventilation be needed. In cases of tension pneumothorax the patient may be tachycardic, hypotensive, and tachypnoeic.
Imaging features Plain film (Figs. 4.9 and 4.10) The visceral pleura is seen as a thin curvilinear line which parallels the chest wall (a skin fold is usually much thicker). The air within the chest cavity will make the hemithorax appear ‘blacker’, and no lung markings are visible beyond the line of pleura. The presence of rib fractures, subcutaneous emphysema, and bullae should provoke a thorough search for a pneumothorax. Signs of a tension pneumothorax on CXR include: • Unilateral hyperlucency. • Deviated trachea and mediastinum away from the abnormal side. • Depression of the ipsilateral hemidiaphragm. The immediate response is needle decompression. Remember—when the patient is supine a pneumothorax is more difficult to detect, as the air collects superiorly, overlying the lungs, and the pleural edge is often not visible. The heart borders and diaphragms become unusually well defined. The affected lung base becomes lucent (black) which progresses to the deep sulcus sign, where the costophrenic angle is depressed, as pressure increases. Ultrasound Ultrasound can be used to diagnose pneumothorax (in specialist hands!) However, it is rarely used in the acute setting. CT CT is the gold standard test for detecting and localizing pneumothorax, and may be necessary to guide percutaneous drainage.
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In addition, CT can help clarify the presence of bullae, which may simulate pneumothorax on the plain film.
Information for the radiologist • Any history of trauma. • Previous history of pneumothorax. • Recent iatrogenic procedure.
Fig. 4.9 CXR of patient with sudden onset of chest pain and dyspnoea, showing a pleural edge at the right apex with absent lung markings lateral to it, indicating a pneumothorax. Note that the mediastinum remains central and the diaphragms are normally positioned.
Fig. 4.10 CXR of a tension pneumothorax on the right. The collapsed lung is opacified, the mediastinum is shifted away from the affected side and the ipsilateral diaphragm is depressed. This needs urgent decompression.
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Wegener’s granulomatosis Disease of unknown aetiology causing granulomatous inflammation of small- and medium-sized blood vessels in the respiratory tract, kidneys, and other organs.
Clinical presentation • Upper respiratory tract symptoms: rhinitis, sinusitis and otitis media. • Pulmonary involvement is very common (up to 90%) and may cause dyspnoea, cough, haemoptysis, chest pain, or stridor due to airway stenosis. • Progressive renal failure secondary to necrotizing glomerulonephritis. • Arthralgia and myalgia. • Epistaxis. • Scleritis.
Imaging Plain film (Figs. 4.11 and 4.12) • Patchy infiltrates and consolidation due to pulmonary haemorrhage. • Cavitating nodules. • Pleural effusion. • Atelectasis. • Pneumothorax (uncommon). Nodules and consolidation may resolve without a trace over a period of months leaving a normal radiograph. CT • Tracheal/bronchial stenosis (can be life threatening). • Nodules which frequently cavitate. These may be surrounded by a ‘halo’ of ground glass opacification due to haemorrhage. • Peripheral pulmonary infarcts. CT of the sinuses will show any nasal involvement. Ultrasound Renal ultrasound may show small kidneys of increased echogenicity, and guide biopsy. Nuclear medicine Active areas of disease will show increased uptake on gallium scans. MRI Brain/spinal imaging may show neuritis.
Information for the radiologist • Presenting symptoms. • Renal function. • Vasculitic screen: c-ANCA (centrally accentuated antineutrophil cytoplasmic antibody test): usually but not always positive. • Past medical history (e.g. malignancy, PE, rheumatoid disease, immunosuppression) will help to guide differential diagnosis. • Consideration of lung/renal biopsy? (Would need current blood tests including coagulation screen.)
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Fig. 4.11 CXR of a young man revealing several cavitating mass lesions in both lungs. The patient presented with vasculitic rash, haematuria, and dyspnoea.
Fig. 4.12 CXR of the same patient as Fig. 4.11 several months later following immunosuppressive treatment. The lesions have all regressed, leaving residual scar tissue and atelectasis.
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Pulmonary hypertension Defined as sustained systolic pulmonary artery pressure of >25mmHg at rest or >30mmHg during exercise with increased pulmonary vascular resistance. May be primary (idiopathic) or secondary to cardiac, pulmonary or hepatic disease. Causes include: • Increased pulmonary blood flow secondary to congenital heart disease or high-output cardiac states. • Increased pulmonary vascular resistance, e.g. PE, connective tissue diseases, pulmonary fibrosis, or pulmonary venous hypertension.
Clinical presentation Chest pain, dyspnoea, haemoptysis, fatigue, or syncope. There may be signs of right heart failure (raised JVP, hepatomegaly, ascites, oedema).
Imaging Plain film (Fig. 4.13) CXR may reveal cardiomegaly and enlarged central pulmonary arteries with peripheral pruning. There may be signs of underlying pulmonary parenchymal disease, e.g. COPD. Echocardiography Demonstrates right ventricular hypertrophy and tricuspid regurgitation and is a non-invasive method of estimating pulmonary arterial pressure. CT May reveal: • Right atrial and ventricular hypertrophy. • Enlarged central pulmonary arteries, occasionally with calcification. • Pruning of peripheral arteries. • Pulmonary emboli. • Pulmonary parenchymal disease. MRI Evaluates cardiac chambers, wall motion, stroke volume, and right ventricular EF (often reduced). Can also be used to depict pulmonary vasculature and assess shunts. Pulmonary angiography Allows accurate measurement of arterial pressures. Right heart catheterization can be performed to assess cardiac function and pulmonary flow dynamics.
Information for the radiologist • Presenting symptoms. • Relevant past medical history including risk factors for pulmonary hypertension, e.g. congenital heart disease, sickle cell anaemia. • Clinical question, e.g. ?PE. ?Interstitial lung disease.
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Fig. 4.13 CXR of a 54-year-old man with severe breathlessness reveals marked enlargement of the pulmonary trunk and main pulmonary arteries with relative oligaemia in the lungs themselves, in keeping with primary pulmonary hypertension.
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Solitary pulmonary nodule A single spherical lesion of 3cm or less in diameter, completely surrounded by lung without any associated atelectasis or lymphadenopathy.
Clinical presentation Often an incidental finding on chest radiograph or CT. The main concern is usually to exclude malignancy. Discussion in multidisciplinary meetings is often required to define an appropriate management strategy.
Imaging Plain film CXR often identifies the solitary pulmonary nodule (SPN) initially. Dualenergy radiography can help determine if the nodule is calcified and does indeed lie within the lung. CXR may be able to characterize nodules but frequently CT is required (Figs. 4.14 and 4.15). CT More sensitive than plain film for detection of SPNs. May be used for characterization, to guide biopsy, or to monitor indeterminate nodules. To infer benignity, a nodule must be stable in volume for a period of at least 2 years. Certain features can help in characterization: • Calcification: most patterns of calcification are associated with benign conditions such as hamartomas and TB. However, eccentric calcification is associated with malignancy. • Density: e.g. fat indicates hamartoma or lipoma. • Margins: speculated or smooth. • Cavitation and wall thickness: thick-walled cavities suggest malignancy. • Enhancement pattern: minimal enhancement suggests benignity. • Size: unreliable but larger nodules are generally more likely to be malignant. Nuclear medicine Increased uptake on PET suggests malignancy though infection and inflammation can cause false positive results. PET lacks sensitivity for bronchoalveolar cell carcinoma and carcinoid, or if the nodule is 300ml are present. • Lateral radiographs are better at detecting small effusions and can detect as little as 25ml. • Hemidiaphragm and costophrenic recesses are obscured. • Meniscus-shaped upper surface with the lowest point in mid-axillary line. • On supine radiograph, hazy increased opacity on affected side, which does not obscure bronchovascular markings. CT • CT chest with contrast should be performed in all patients with undiagnosed effusion, especially if unilateral. • Nodular pleural thickening suggests malignancy, smooth pleural thickening is seen in benign conditions such as empyema. • In transudative effusions the pleura should not be visible at all. • May be other findings such as cardiomegaly, asbestos plaque, abdominal disease. Ultrasound • Ultrasound is used to identify and localize fluid prior to aspiration or drainage. It also may be used to guide pleural biopsy. • NCEPOD (National Confidential Enquiry into Perioperative Deaths) have recently recommended all drainage of pleural effusions be ultrasound-guided. • Ultrasound is better than CT at showing loculation and septae within an effusion.
Information for the radiologist • Relevant medical history. • Features of infection if present. • Asbestos exposure.
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Fig. 4.32 PA CXR showing a large pleural effusion filling much of the right chest. Note the shift of the mediastinum away from the opacity and the meniscus extending up over the apex of the lung.
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Interstitial lung disease Inflammation of the supporting structures (interstitium) of the lung. Frequently results in scarring and fibrosis.
Clinical presentation Common symptoms include dyspnoea and a dry cough. There may be clubbing and inspiratory crepitations on auscultation. A large number of causes are described including: • Idiopathic, e.g. idiopathic pulmonary fibrosis (IPF), sarcoidosis. • Inhaled substances, e.g. asbestosis, silicosis. • Drug induced, e.g. amiodarone, gold. • Infective causes, e.g. tuberculosis, atypical pneumonia. • Connective tissue diseases, e.g. scleroderma, rheumatoid arthritis. • Radiotherapy. The diagnosis can often be made by integrating imaging findings with a detailed history, though occasionally bronchoalveloar lavage or lung biopsy is required.
Imaging Plain film Often abnormal with increased reticular (‘linear’) or reticular-nodular (‘linear and nodular’) lung markings. Fibrosis is usually associated with volume loss. CT HRCT is the preferred study. Demonstrates the smallest functional unit of the lung, the secondary pulmonary lobule, allowing abnormalities to be accurately localized. Interstitial thickening is seen as either a reticular or reticular-nodular pattern. Additional appearances may include: • Honeycombing (small cystic spaces due to fibrosis). • Nodules, e.g. in silicosis. • Cysts, e.g. in histiocytosis. • Bronchiectasis secondary to fibrosis (traction bronchiectasis). • Lymphadenopathy, e.g. sarcoidosis, malignancy. • Pleural plaques and calcification, e.g. asbestosis. The distribution of disease is also important in narrowing the differential diagnosis, for example: • Upper lobe predominance: TB, sarcoid. • Lower lobe predominance: IPF, asbestosis, rheumatoid. • Well-defined localized area: post-radiotherapy.
Information for the radiologist • • • •
Presenting symptoms and duration of illness. History of malignancy/atypical infection/smoking. Potential environmental and drug causes, e.g. asbestos exposure. Lung function tests.
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Fig. 4.33 PA CXR of a 60-year-old patient following a single lung transplant for idiopathic pulmonary fibrosis. Note the significant volume loss in the native fibrotic lung when compared to the transplanted left lung.
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Connective tissue disease and the lung Most of the connective tissue diseases (CTDs), including rheumatoid, systemic sclerosis, SLE, and dermatomyositis affect the lung in some way. Each condition has a different pattern of common effects, but there is considerable overlap between them.
Clinical presentation Depends on severity of lung involvement and associated features of the underling disease. In many cases patients will present with lung involvement before any other manifestations of CTD. Common symptoms are non-specific and include progressive exertional dyspnoea and dry cough. Haemoptysis occurs in patients with diffuse alveolar haemorrhage syndromes and vasculitis. Chest pain is uncommon but pleuritic chest pain can occur in patients with rheumatoid arthritis or SLE. Signs to look for include finger clubbing, a maculopapular rash, Raynaud’s phenomenon, telangiectasia, peripheral lymphadenopathy, and inspiratory crackles on auscultation.
Imaging Plain film (Fig. 4.34) Rheumatoid lung • Unilateral pleural effusion is a frequent manifestation. • Fibrosis. • Peripheral necrobiotic nodules. • Bronchial wall thickening/bronchiectasis. • Cor pulmonale: cardiac enlargement and pulmonary artery enlargement. SLE • Pleural and pericardial effusions. • Non-resolving consolidation. Systemic sclerosis • Fibrosis. • Oesophogeal dilatation. CT (Fig. 4.35) Shows the same features as CXR but in better detail with increased sensitivity and specificity. Fluoroscopy Barium swallow useful in assessing oesophageal dysmotility often seen in systemic sclerosis.
Information for the radiologist • Duration of symptoms. • Serological results.
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Fig. 4.34 CXR revealing widespread calcification within the soft tissues of the chest wall and distortion of the vascular pattern in the lung due to interstitial lung disease. The patient was proven to have dermatomyositis.
Fig. 4.35 Axial CT section from a patient with scleroderma and end-stage pulmonary fibrosis.
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Pneumoconiosis • The term pneumoconiosis refers to the accumulation of inorganic dust in the lungs and the tissue reaction to its presence. • Silica, asbestos, coal, and beryllium are the most commonly encountered causes, usually inhaled during occupational exposure. • The most important factors in the development of pneumoconiosis are the duration and intensity of exposure to the dust.
Clinical presentation • Patients with simple coal worker’s pneumoconiosis are usually asymptomatic. They may rarely report cough or sputum production. • Complicated coal worker’s pneumoconiosis (CWP) produces cough, dyspnoea, and lung function impairment. In advanced disease, cor pulmonale may result.
Imaging Plain film (Fig. 4.36) Simple CWP • Small well-circumscribed nodules between 2–5mm with a predominant upper zone distribution. • No progression after cessation of dust exposure. Complicated CWP (progressive massive fibrosis, PMF) • Large coalescent opacities >1cm. • Typically peripheral in mid and upper zones: eventual hilar migration. • May develop/progress after cessation of dust exposure. • Calcified hilar lymphadenopathy. • Loss of volume in upper zones. Cavitation within the upper zone opacities may be seen due to ischaemic necrosis or possibly to superimposed TB. CT (Fig. 4.37) • Small well-defined nodules with upper zone predominance. • Irregular conglomerate masses in both upper zones; may have cavitated. • Focal centrilobular emphysema. • Calcified mediastinal lymphadenopathy (peripheral calcification described as ‘eggshell’).
Information for the radiologist • • • •
Respiratory function. Occupational history. Smoking history. Any worrying or unusual symptoms.
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Fig. 4.36 PA CXR of patient with progressive massive fibrosis showing bilateral mass-like opacities at both hila, with volume loss in the upper lobes and widespread nodularity throughout the lungs, also with an upper lobe predominance. The patient had a long history of coal dust exposure.
Fig. 4.37 Axial CT of the same patient as in Fig. 4.36, showing the bilateral mass-like lesions, nodularity, and architectural distortion of PMF.
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Sarcoidosis Sarcoidosis is a multisystem disorder of unknown cause. The diagnosis is usually made on the basis of wide ranging clinical and radiological manifestations, and is supported histologically by the presence of non-caseating granulomas. There is a worldwide distribution, although a geographic predilection for African American, Danish, and Swedish populations has been described. It typically affects young to middle-aged adults, with a slightly higher incidence in women. Morbidity and mortality is usually related to pulmonary disease with a 1–5% fatality rate resulting from severe respiratory or cardiac dysfunction.
Clinical presentation The clinical course of sarcoidosis varies considerably from self-limiting illness in up to 2/3 of patients, to chronic progression in 10–30% of cases. Dry cough, dyspnoea, and chest pain occur frequently. Lofgren’s syndrome is a form of sarcoidosis that manifests as fever, arthralgia, erythema nodosum, and bilateral hilar lymphadenopathy.
Imaging Plain film (Fig. 4.38) Findings include intrathoracic lymphadenopathy and parenchymal abnormalities often with an upper zone distribution. A clinical staging system based on the pattern of chest radiographical findings is used to monitor disease progression and prognosis: • Stage 0: normal chest radiograph. • Stage 1: lymphadenopathy only. • Stage 2: lymphadenopathy with parenchymal infiltration. • Stage 3: parenchymal disease only. • Stage 4: pulmonary fibrosis. Ultrasound Little routine role but used to assess abdominal involvement and aid biopsy of accessible nodes. CT (Fig. 4.39) Thoracic involvement is more clearly demonstrated than with CXR alone. CT will show the pattern of mediastinal involvement and subtle abnormalities such as pleural nodularity and bronchovascular thickening. MRI May be useful in cases of cardiac and neurological involvement.
Information for the radiologist • Presenting features. • Any concerns for alternative diagnoses such as TB or lymphoma. • Serum ACE.
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Fig. 4.38 CXR showing bilateral hilar adenopathy secondary to sarcoidosis.
Fig. 4.39 Axial HRCT slice of patient with Sarcoid showing perihilar nodularity, thickening of the bronchovascular structures, and beading of the fissures.
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Benign asbestos-related disease Asbestos is a naturally occurring, fibrous silicate and exposure primarily occurs in occupational settings. The spectrum of asbestos-related thoracic diseases includes benign and malignant pleural disease: • Benign pleural effusions are the earliest sign of disease (with a latency period of 8–10 years after exposure), and are usually small unilateral exudates. • Focal pleural plaques are the radiological hallmark of prior asbestos exposure, and may or may not calcify. • Diffuse pleural thickening is smooth and uninterrupted, involving the visceral pleura and extends over at least 25% of the chest wall. • Round atelectasis specifically refers to an area of atelectatic lung adjacent to pleural thickening. • Asbestosis is a term reserved for fibrosis due to asbestos exposure.
Clinical presentation Patients are usually asymptomatic but asbestos effusions can present with episodes of pleuritic chest pain and fever. Diffuse pleural thickening may be sufficient to restrict chest movement and lead to breathlessness.
Imaging Plain film (Fig. 4.40) • En face calcified plaques are seen as well-defined opacities with irregular margins, sometimes describes as resembling a ‘holly leaf’. • Diffuse pleural thickening causes blunting of the costophrenic angles, is ill defined, and more extensive in distribution than focal plaque disease. • Asbestosis manifests as pulmonary fibrosis in the basal, subpleural zones along with calcified plaque. CT (Fig. 4.41) Benign pleural plaques are focal, smooth opacities, usually 1cm. CT can suggest pleural malignancy but is not in itself diagnostic, nor can it differentiate accurately between mesothelioma or metatstic pleural disease. It may be used to perform targeted pleural biopsy. MRI Limited role—sometimes used if surgical resection being considered but this is rare. Nuclear medicine • PET-CT is not routinely used in mesothelioma unless curative surgery is being considered. • Can be useful in cases of metastatic pleural malignancy of unknown primary.
Information for the radiologist • Asbestos history. • Any previous malignancy.
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Fig. 4.43 Axial CT slice from a patient who presented with shortness of breath and right-chest pain. The scan reveals pleural thickening of >1cm in depth completely encasing the lung. Biopsy confirmed mesothelioma.
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Mediastinal masses An abnormal soft tissue mass within the mediastinum.
Clinical presentation Wide range of presentations depending on location and nature of the mass. May present with chest pain, stridor, dyspnoea, dysphagia, SVC obstruction, hoarse voice, weight loss, back pain, or ruptured aneurysm, for example. May also be an incidental finding.
Imaging Plain film (Fig. 4.44) PA and lateral chest radiographs may identify and localize the mass and can help to guide further investigation. CT (Fig. 4.45) Usually performed for characterization and occasionally to guide biopsy. Identifies calcification, cystic areas, and vascular structures better than plain film. Allows accurate localization of the mass which narrows the differential diagnosis: • Anterior mediastinum—anterior to the pericardium, ‘the 4 T’s’: • Thymoma. • Thyroid. • Teratodermoid (germ cell tumours). • ‘Terrible’ lymphoma. • Middle mediastinum—the heart, aortic root and pulmonary vessels: • Bronchogenic cysts and tumours. • Ascending aortic aneurysm. • Lymphadenopathy. • Posterior mediastinum—posterior to the pericardium: • Oesophageal tumour, achalasia, or duplication cysts. • Descending aortic aneurysm. • Neurogenic tumour. • Meningocoele. • Extramedullary haematopoiesis. Nuclear medicine Certain tumours show increased uptake on PET, e.g. lymphoma. Scintigraphy can be used to identify thyroid goitre, ganglioneuromas and phaeochromocytomas. MRI Excellent at depicting neurogenic tumours and spinal abnormalities. Ultrasound Useful to assess the thyroid though will not visualize retrosternal areas adequately.
Information for the radiologist • • • •
Age and sex of patient. Presenting symptoms. Previous imaging. Management plan, e.g. biopsy.
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Fig. 4.44 PA CXR showing a large soft tissue mass arising from the mediastinum. Note the descending aorta is well seen, as are the hilar structures, placing the mass within the anterior mediastinum.
Fig. 4.45 CT of the same patient as Fig. 4.44, confirming the mass lies within the anterior mediastinum, enhances with contrast and contains some peripheral necrosis. CT-guided biopsy confirmed thymoma.
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Vascular differential diagnosis Global cardiomegaly 94 Enlarged left atrium 94 Enlarged left ventricle 94 Enlarged thoracic aorta 94 Enlarged pulmonary arteries 95
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Vascular differential diagnosis
Global cardiomegaly • • • •
Ischaemia. Cardiomyopathy. Pericardial effusion. Multiple valvular disease.
Enlarged left atrium • Increased pressure: • Mitral stenosis. • Atrial myxoma. • Left ventricular failure. • Increased flow: • Mitral incompetence. • Right-to-left shunt.
Enlarged left ventricle • Increased pressure: • Hypertension. • Aortic stenosis. • Coarctation. • Increased flow: • Aortic incompetence. • Mitral incompetence. • Right-to-left shunt. • Weakened muscle: • Ischaemia. • Cardiomyopathy.
Enlarged thoracic aorta • Aortic stenosis: • Post-stenotic dilatation of ascending aorta. • Atherosclerosis. • Hypertension. • Infection: • Syphilis. • Endocarditis. • Coarctation. • Marfan’s syndrome. • Dissection. • Post traumatic.
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Enlarged pulmonary arteries Dilated pulmonary trunk only • Post-stenotic dilatation (pulmonary valve stenosis).
Dilated central pulmonary arteries/small peripheral vessels • • • •
Primary pulmonary hypertension. Chronic pulmonary embolic disease. Chronic lung disease. Eisenmenger’s syndrome.
Dilated central and peripheral vessels • Left-to-right shunt.
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Vascular presenting syndromes Intermittent claudication 98 Rest pain 98 Acutely painful blue leg 99
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Intermittent claudication When atheroma narrows the blood vessels supplying the lower limb, blood flow is reduced and with it the amount of oxygen that can be taken up by the tissues.
Presentation Muscle ischaemia presents in the same basic way, whether it be cardiac (angina) or in the lower limb (claudication). Patients suffer pain induced by exercise, relieved by rest. In claudication the pain is typically felt in the calves, and is brought on by walking. Risk factors include: • Increased age. • Smoking. • Hypertension. • Family history.
Imaging Ultrasound Doppler ultrasound can be used in clinic to assess the patency of peripheral vessels, and follow up treated areas, but is not accurate enough to be used as a sole presurgical assessment. CT Can be used to visualize the peripheral vascular tree, but the radiation dose is high, and most centres prefer to use MRI. MRI Allows accurate assessment of the peripheral vasculature, identifying stenoses and occlusions in the main lower limb vessels down to the foot. Routinely used in the work-up of patients with claudication to plan intervention and follow-up patients after treatment. Angiography Diagnostic angiography has largely been superseded by MRI, but interventional radiologists have an ever increasing role in the treatment of these patients.
Rest pain Once blood flow to the foot becomes critical, oxygen supply cannot match demand even at rest and the patient suffers continual pain in the lower limb. Imaging techniques are the same as for claudication.
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Acutely painful blue leg Sudden occlusion of an artery results in acute ischaemia of the structures in that vascular territory. The commonest cause is thrombus, but cases can be iatrogenic, traumatic, or due to other embolic phenomena.
Presentation Patients present with an acutely swollen, painful, pulseless leg. Capillary refill will be reduced and the limb is cold to the touch. Risk factors include: • Atrial fibrillation. • Atheroma elsewhere, particularly the aorta. • Smoking.
Imaging Plain film Little acute role but CXR may reveal cardiomegaly as a clue to an underlying cardiac cause. Ultrasound Echo should be performed to look for intra-cardiac thrombus, shunts, and valvular vegetations. Peripheral Doppler ultrasound can be used to confirm the clinical impression of absent flow in the peripheral arteries. CT Can identify the level of occlusion, but more common role in the assessment of the aorta for atheromatous disease which may account for embolus formation. MRI Accurate localization of the site of thrombus and the condition of the rest of the peripheral vascular tree. Angiography In classic cases may still be used as the frontline diagnostic test, but this role now often given over to MRI. Angiography does allow catheters to be placed directly against the causative thrombus however, allowing intraarterial thrombolysis to be administered, or other mechanical treatments if appropriate.
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Chapter 7
Vascular conditions Aortic dissection 102 Thoracic aneurysm 104 Acute myocardial infarction 106 Cardiomyopathy 108 Coarctation of aorta 110 Aortic stenosis 112 Mitral valve disease 114 Congenital heart disease 116 Ischaemic heart disease 118 Cardiac tumours 120 Abdominal aortic aneurysm 122 Peripheral vascular disease: diagnosis 124 Peripheral vascular disease: radiological treatments 126 IVC filter insertion 128 Arteriovenous fistula 130
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Aortic dissection Dissection occurs when blood is able to track between the layers of the vessel wall, creating a false lumen beneath the intima. Dissection is associated with hypertension, some connective tissue diseases, or may be iatrogenic.
Clinical presentation Acute dissection will cause pain, often with associated neurological abnormalities or pulse and blood pressure inequalities. Classically the pain is described as having a ‘tearing’ quality, between the shoulder blades. Aortic dissection classification and treatment depends on whether or not the ascending aorta is affected: • Type A dissection involves the aorta proximal to the origin of the left subclavian artery and normally requires surgical treatment. • Type B dissection only involves the aorta distal to the left subclavian and is commonly treated medically with antihypertensives.
Imaging features Plain film CXR is often normal. Classical findings in dissection include: • Widened mediastinum or aortic arch. • Tracheal deviation. • Depression of the left main bronchus. • Left pleural effusion. Ultrasound TOE can be used to diagnose thoracic aortic aneurysms and dissections at the bedside; however, it is highly operator dependent, less accurate than CT, and not readily available in many centres. CT Contrast-enhanced CT is the modality of choice for making the diagnosis and demonstrating the relevant anatomy. Allows accurate visualization of the dissection flap (Figs. 7.1 and 7.2), true and false lumens, and affected branches. May demonstrate haemorrhage into the aortic wall, a sign of impending dissection and managed in much the same way. CTA required for assessment prior to percutaneous stent placements. MRI Long procedure time and requirement for specialist (non-magnetic) monitoring equipment severely limits its role in acutely unwell patients. Fluoroscopy No role in acute diagnosis, however endovascular stents may be used to treat dissection flaps in the descending aorta.
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Information for the radiologist • • • •
Time since onset of symptoms. Blood pressure in both arms. Signs of shock. Previous history or risk factors for aneurysm.
Fig. 7.1 Axial CT slice through the aortic arch in a patient presenting acutely with severe chest pain and signs of cardiovascular shock reveals a large dissection flap extending the length of the arch.
Fig. 7.2 Axial CT slice from the same patient as Fig. 7.1 at the level of the aortic root reveals a large pericardial effusion secondary to haemorrhage. Note also the dissection flap in the descending thoracic aorta.
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Thoracic aneurysm An aneurysm is present when the vessel diameter exceeds 150% of normal. Thoracic aneurysms may be secondary to atherosclerosis, infection, inflammation, or trauma. Aneurysms of the arch and descending aorta are usually secondary to atherosclerosis, whilst those in the ascending aorta are seen in conditions such as aortic valve stenosis or Marfan’s syndrome. Risk of rupture increases with size, and is greater for aneurysms of the descending aorta than the ascending aorta.
Clinical presentation • Many patients with thoracic aneurysms will be asymptomatic, diagnosed incidentally during investigation of other conditions. • Ascending aortic aneurysms may involve the aortic root causing aortic regurgitation and congestive cardiac failure. • Compression of local structures may cause wheeze or breathlessness (trachea), hoarseness (left recurrent laryngeal nerve) or dysphasia. • Rupture occurs most commonly into the left pleural space and presents with pain, hypotension, and shock. • Thromboembolism is another potential complication, causing stroke, lower limb ischaemic or mesenteric ischaemia. Symptoms will depend upon the area affected.
Imaging features Plain film Ascending aortic aneurysm may not be visible on plain film, or may give a bulge to the right mediastinum. The presence of curvilinear calcification in the aortic wall may be an indication of underlying aneurysm formation. Ultrasound TOE can be used to diagnose thoracic aortic aneurysms at the bedside; however, it is highly operator dependent, less accurate than CT, and not readily available in many centres. CT Contrast-enhanced CT is the modality of choice for making the diagnosis, demonstrating the relevant anatomy and is the modality of choice if acute rupture is suspected (Fig. 7.3). CT is also used for accurate assessment prior to percutaneous stent placement. MRI Can be used to evaluate thoracic aneurysms, and allows interrogation of the aortic valve if post-stenotic dilation or aortic regurgitation are factors. If long-term follow-up is required, allows accurate assessment without the radiation burden of CT. Long procedure time and requirement for specialist (non-magnetic) monitoring equipment severely limits its role in acutely unwell.
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Fluoroscopy No role in acute diagnosis, however endovascular management of thoracic aortic aneurysms is now commonplace.
Information for the radiologist • • • •
Time since onset of symptoms. Blood pressure in both arms. Signs of shock. Previous history or risk factors for aneurysm.
Fig. 7.3 Axial CT from a patient who presented acutely with cardiovascular compromise, revealing active haemorrhage from an aneurysm of the proximal descending aorta, with blood accumulating in the left chest. The patient died in the CT suite.
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Acute myocardial infarction Acute myocardial infarction (MI) is caused by sudden occlusion of a coronary artery leading to ischaemia and death of cardiac myocardium. Risk factors include increasing age, previous ischaemic heart disease, cigarette smoking, diabetes, hypertension, and hypercholesterolaemia.
Clinical presentation Central chest pain is the sine qua non of acute myocardial infarction. The pain is usually centred over the lower left hemithorax, radiating to the left shoulder, jaw, and left arm. However, features may be atypical and occasionally present as upper abdominal pain. An ECG will usually demonstrate ST-T changes confirming the diagnosis. A subset of patients present without any chest pain or ECG changes and the diagnosis is made based on serum troponin rise. Apart from intrathoracic conditions such as aortic dissection, pulmonary embolism, pneumonia, reflux oesophagitis, and pleural effusion, upper abdominal diseases such as peptic ulcer exacerbation, acute cholecystitis, and perforation peritonitis may all mimic an acute MI.
Imaging Traditionally, imaging used to be of limited value in the initial evaluation of acute MI. However, with the advent of primary percutaneous intervention (PCI) and ‘triple rule-out’, this is changing. Plain film Chest radiographs may be completely normal unless patient develops acute left ventricular failure. Echocardiogram May demonstrate: • Regional wall motion abnormalities. • Mitral insufficiency. • Ventricular septal rupture. • Pericardial effusion. Measured ejection fraction (EF) will provide an indication of the effect of the MI on cardiac function, which has prognostic relevance. Coronary angiography With the advent of primary PCI, coronary angiography and left ventriculography are performed in the acute setting with a view to proceed to appropriate intervention. It is performed usually by puncturing a femoral or (if necessary) brachial artery. Using highly selective catheters and under fluoroscopic guidance, the coronary ostia are selectively engaged and small volumes of contrast agent injected to demonstrate the coronary arteries and any occlusion or stenoses. This then acts as a road map for further intervention. Nuclear medicine No role in the imaging of acute MI.
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Have a greater role in ischaemic heart disease (see b Ischaemic heart disease, p. 118). CT CT scanning does not have an established role in the management of acute ST elevation MI. However, research is continuing into the use of CT to investigate patients who present with acute chest pain without ECG changes of MI as it can be used to simultaneously assess the coronary arteries, aorta, and pulmonary arterial tree to exclude significant coronary artery disease, aortic dissection, and acute pulmonary embolism. At present this remains a specialized investigation and is not widely available.
Information for the radiologist • • • • •
Duration of symptoms. Risk factors. ECG changes. Blood results. Heart rate and rhythm.
Fig. 7.4 CT reconstructed in the plane of the cardiac short axis in a patient with resistant heart failure following MI, demonstrating a post infarct VSD.
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Cardiomyopathy A structural or functional disease of heart muscle that is not secondary to ischaemia, valvular pathology, hypertension, or congenital abnormality. There are several distinct forms, including: • Enlargement of the cardiac chambers (dilated cardiomyopathy, DCM). • Hypertrophy of the cardiac muscle (hypertrophic CM, HCM). • Loss of elasticity in the ventricle and reduced capacity to expand (restrictive CM, RCM).
Clinical presentation • Clinical presentation is variable and includes fatigue, dyspnoea, chest pain, palpitations, and syncope. • Diagnosis may occur through investigation of other family members after a sudden death or newly confirmed diagnosis. • Causes of DCM include myocarditis (viral and bacterial), pregnancy, alcohol, and muscular dystrophies. • Autosomal dominant inheritance is found in HCM; however, 50% of cases are sporadic. • Examination findings include a displaced or forceful apex beat (in DCM and HCM respectively). • HCM is associated with an ejection systolic murmur. • Kussmaul’s sign (elevation of JVP on inspiration) is found in RCM. • Progression leads to signs and symptoms of cardiac failure.
Imaging features Plain film (Fig. 7.5) • Cardiomegaly is present in DCM and is a late feature of HCM. • Heart failure develops with progressive disease. Ultrasound/echocardiography DCM • Diffuse 4-chamber dilatation. • Poor systolic function with normal left ventricular wall (LV) thickness. HCM • Asymmetric or symmetric LV wall thickening. • Systolic anterior motion of the mitral valve. DCM and HCM are both associated with mitral valve regurgitation. RCM • Poor late diastolic filling of the left ventricle. • Dilatation of the left atrium with normal systolic function. CT • Can assess muscle thickness and heart size. • Non-calcified pericardium 70% are considered candidates for endarterectomy. CT (Fig. 10.1) All patients with a suspected stroke should have a non-contrast CT (NCCT) of the brain within 24 hours. Immediate imaging (within 1 hour) is indicated in the following circumstances: • Indications for thrombolysis or early anticoagulation treatment. • Anticoagulant treatment. • Known bleeding tendency. • Glasgow Coma Score (GCS) 2cm in size but it is not so sensitive for very small lesions. MRI They are usually darker than brain tissue on T1 and show intense enhancement following IV gadolinium (Fig. 10.7). On T2 imaging the tumour will appear bright. Angiography The vascular supply is usually from the external carotid artery. Displacement of the nearby vessels is the most common finding at angiography.
Information for the radiologist • Does the patient have any other stigmata of neurofibromatosis, e.g. multiple neuromas, café au lait spots, or axillary freckling? • Are the symptoms unilateral or bilateral?
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(a)
(b) Fig. 10.7 a) Coronal image. b) Axial image, both are T1-weighted post-gadolinium images. The arrow shows the normal right vestibulocochlear nerve with no evidence of enhancement. The arrowhead shows the abnormal nerve on the other side with marked enlargement and significant enhancement.
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Glioma Glioma describes a tumour, which arises from the glial cells. The most common location is the brain, but they also occur in the brainstem, the spinal cord, and the optic nerve. The tumours are further classified according to cell of origin, location, and by grade.
Classification Cell of origin • Astrocyte: astrocytoma. Glioblastoma multiforme is the most common type of astrocytoma. These are very aggressive. • Ependyma: ependymoma. • Oligodendrocyte: oligodendroglioma. • Medulloblast: medulloblastoma. Location Gliomas may be supratentorial or infratentorial. In adults they are mostly supratentorial and in children mostly infratentorial. Grade • Low grade: these tend to be slow growing benign and carry a better prognosis. • High grade: tend to be more aggressive, malignant, and carry a worse prognosis.
Clinical presentation This will depend upon the area affected. Brain gliomas cause signs and symptoms associated with raised intracranial pressure such as headache, nausea, vomiting, decreased conscious level, as well as seizures and cranial nerve palsies. Generalized symptoms such as memory loss and personality change are also common. A glioma originating in the spinal cord may manifest with weakness and paraesthesia in the limbs or with pain in the spine.
Imaging CT On NCCT gliomas appears as an irregular and poorly defined low-density area causing mass effect. There will usually be enhancement following IV contrast but the pattern is variable and non-specific. MRI (Fig. 10.8) Tumours are typically low signal on T1 imaging and high signal on T2 imaging, usually with surrounding oedema. They enhance following gadolinium. Angiography Whilst this technique is unlikely to be used for diagnostic purposes, it may be performed prior to surgical intervention and will often show an extremely irregular vascular pattern.
Information for the radiologist • Focal neurological signs. • Are there any signs of cord compression or raised intracranial pressure?
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(a)
(b) Fig. 10.8 A 25-year-old patient was referred for MRI as they had severe intractable headache with vomiting. a) T2W axial image which shows extensive oedema with a more complex central abnormality in the right. b) T1W Gd axial image showing marked enhancement of the lesion. This was proven to be an astrocytoma.
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Meningioma This is the most common extra-axial tumour in adults. Although usually a benign tumour it can, rarely, undergo malignant transformation. It arises from the meninges and is usually supratentorial in location (90%). They are usually slow growing but may be surgically resected if causing significant symptoms. The peak age incidence is 45 years and they are relatively rare in children. There is no known cause but risk factors include: • Neurofibromatosis type 2. • Radiation to the head and neck. • Exposure to female hormones and breast cancer.
Clinical presentation Symptoms are caused either by direct pressure on underlying brain parenchyma, raised intracranial pressure, involvement of cranial nerves, or involvement of surrounding bone and soft tissues. These include nonspecific headaches, seizures, focal weakness, and cranial nerve palsies. However, many are asymptomatic and are purely incidental findings.
Imaging Plain film The most common finding on a plain radiograph would be hyperostosis of the bone adjacent to the meningioma. Calcification within the tumour may also be identified. CT Usually a well-circumscribed hyperdense, mass seen on NCCT, that has a broad based attachment to the dura. They enhance intensely following IV contrast. There is often internal calcification and hyperostosis of the adjacent bone. MRI (Fig. 10.9) On T1 images the lesion will be either low signal or isointense and on T2 will be either isointense or high signal. There is avid contrast enhancement with the administration of gadolinium. Classically a ‘dural tail’ sign will be seen. Angiography Meningiomas are almost always supplied by the external carotid artery and very rarely by the internal carotid artery. A ‘mother in law’ blush is typical, i.e. contrast shows up early and stays late! There is often a sunburst appearance of the feeding vessels.
Information for the radiologist • Previous history of radiotherapy. • Does the patient have neurofibromatosis?
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(a)
(b) Fig. 10.9 a) Axial T1-weighted post gadolinium image. b) Coronal T1-weighted post gadolinium image. The arrows point to a well-defined enhancing lesion attached to the posterior border of the petrous bone consistent with a small meningioma.
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Brain metastases This is one of the most feared complications of systemic cancer by many patients. Metastases are the most common of the intracranial neoplasms and 6 primary tumours account for the majority of all brain metastases. These are: lung, breast, colon, renal, melanoma, and choriocarcinoma.
Clinical presentation Symptoms are either usually caused by a rise in intracranial pressure with symptoms such as nausea and vomiting, headache, and confusion, or by a focal destruction of neurons at the site of the metastasis producing limb weakness, seizures, visual defects, or speech disturbance. Approximately 2/3 of all brain metastases are symptomatic.
Imaging Plain film These are rarely used but lytic or sclerotic lesions on a skull radiograph may be seen if there is bone extension. The most common primary tumours to show this pattern are lung and breast. CT In almost all patients presenting with symptoms suggestive of brain metastases CT will be the first investigation. The typical appearance is of low attenuation areas on NCCT, often multiple and usually found at the grey/ white matter junction. After IV contrast they will usually enhance and more lesions may become apparent. MRI (Fig. 10.10) If there is only one lesion visible on CT then MRI may be used to look for further lesions in order to confirm the diagnosis of metastatic disease. Multiple lesions with surrounding oedema are often seen. These are low signal on T1 and high signal on T2 imaging. Surrounding oedema is usually low signal on T1 and high signal on T2 imaging.
Information for the radiologist Information about any history or cancer is helpful, even if the cancer was some time ago, it may still be relevant.
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(a)
(b) Fig. 10.10 A 54-year-old patient with known breast carcinoma with right-sided visual disturbance. a) Axial T2 image with extensive left occipital oedema with a complex lesion, posteriorly. Low-grade oedema on the contralateral side. b) Axial T1 post-gadolinium-enhanced image demonstrating heterogeneous enhancement of the lesion consistent with a metastasis.
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Pituitary adenoma Background Conditions involving the pituitary gland were first described in 1886 by a French neurologist who studied 2 patients with symptoms suggestive of acromegaly. Pituitary adenomas are benign, slowly growing tumours arising from the anterior lobe of the pituitary gland or adenohypophysis. Most pituitary adenomas arise spontaneously but can also occur as part of the multiple endocrine neoplasia I (MEN I) syndrome.
Clinical presentation Symptoms may be due to either a local pressure effect from the tumour itself on surrounding structures, or may be related to distant endocrine manifestations. A large proportion of patients present with visual symptoms due to compression of the optic nerves.
Classification The tumours are classified according to size: a tumour 10mm is termed a macroadenoma. The functioning tumours are then also classified according to which hormone they secrete. Prolactinoma This is the most common of the pituitary adenomas. In women presenting features include amenorrhoea, infertility, and galactorrhoea. In men symptoms include impotence, low libido, and visual disturbance. Corticotrophic adenoma This is an ACTH-secreting tumour which causes Cushing’s disease—symptoms in this case include weight gain, osteoporosis, muscle weakness, a ‘buffalohump’ at the back of the neck, dryness and thinning of the skin. Somatotrophic adenoma These tumours secrete growth hormone causing gigantism in children and acromegaly in adults. Gonadotropic cell adenoma These tumours are quite rare and secrete luteinizing hormone and folliclestimulating hormone. Symptoms in this case include amenorrhoea and impotence. Thyrotrophic cell adenoma This tumour secretes thyroid-stimulating hormone and produces signs and symptoms of thyrotoxicosis, such as heat intolerance, sweating, tachycardia, and weight loss. This type of adenoma is often large and invasive.
Imaging Plain film Skull radiographs are now relatively rare but occasionally signs of a pituitary adenoma such as enlargement of the sella and erosion of the clinoid processes may be seen. These findings are however non-specific and unreliable!
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CT Microadenomas will usually be seen as a focal hypodensity seen on both non-contrast and contrast-enhanced CT. The adenoma may enhance but not as quickly as the surrounding normal pituitary tissue. Other findings include deviation of the pituitary stalk and erosion of the sella floor. Macroadenomas have variable appearances but most are isoattenuating relative to the cortex on non-enhanced CT scans and show moderate enhancement on enhanced scans. MRI (Fig. 10.11) Coronal T1 images are the most sensitive. Adenomas are usually seen as a focus of low signal on T1 images and a focus of high signal on T2 images.
(a)
(b)
Fig. 10.11 a) Sagittal T1-weighted MRI image demonstrating tumour in the pituitary fossa. b) Post-gadolinium enhanced coronal image shows uniform enhancement throughout. This proved to be a prolactinoma.
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Multiple sclerosis This is a demyelinating disease affecting the spinal cord and the brain. The characteristic lesions are called plaques. Multiple sclerosis (MS) usually affects young adults and is more common in females. There is no known definite cause for this and at the present time no curative treatment is available.
Clinical presentation Due to the nature of the condition it can present with almost any neurological sign or symptom and may progress to cognitive and physical disabilities. The diagnosis requires objective evidence of lesions disseminated in time and space (McDonald criteria1). Lhermitte’s sign is characteristic but not specific to MS. This is an electrical sensation that runs down the back when bending the neck.
Imaging Currently a combination of clinical, laboratory, and radiological tests are used to make the diagnosis. The only radiological investigation of routine value is MRI. MRI (Fig. 10.12) This is the investigation of choice as no other modality can demonstrate the plaques. A combination of T1-weighted, FLAIR, and post-contrast (gadolinium) enhanced can be used to detect these. The whole of the brain and the spinal cord should be covered. Classically plaques are seen in the corpus callosum, U-fibres, temporal lobes, brainstem, cerebellum, and the spinal cord. Temporal lobe involvement is highly specific for MS. Plaques show low signal on T1-weighted, high signal on FLAIR, and enhance post-gadolinium in the brain (after they have been present for a month). Dawson’s fingers are typical for MS—these are ovoid lesions running perpendicular to the ventricles secondary to inflammation around penetrating venules.
Information for the radiologist • Has the patient had any other neurological events? • What is their current neurological status?
Reference 1 McDonald WI, Compston A, Edan G, et al. Recommended diagnostic criteria for multiple sclerosis: guidelines from the International Panel on the diagnosis of multiple sclerosis. Ann Neurol 2001; 50(1): 121–7.
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(a)
(b) Fig. 10.12 a) T2-weighted axial MRI image from the upper cervical spine showing oedema of the cord consistent with a plaque. b) Axial FLAIR image of the brain. This shows multiple periventricular plaques.
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Epilepsy Epilepsy is a common chronic neurological disorder characterized by the occurrence of at least 2 unprovoked seizures 24 hours apart. Seizures result from an abnormal paroxysmal discharge of cerebral cortical neurons.
Classification • Generalized seizures: • Tonic–clonic (grand mal). • Absence (petit mal). • Myoclonic (rare involuntary muscle jerks). • Partial seizures: • Simple partial (no impairment of consciousness, e.g. Jacksonian seizures). • Complex partial (with impairment of consciousness, e.g. temporal lobe epilepsy).
Clinical presentation This depends on the location of seizure activity in the cortex as well as the extent and pattern of its propagation in the brain.
Imaging Neuroimaging should not be routinely requested when a diagnosis of idiopathic generalized epilepsy has been made clinically. CT This can be used to identify gross pathology if MRI is not available or is contraindicated. MRI This is the imaging investigation of choice in individuals with epilepsy, particularly in those: • Who develop epilepsy before the age of 2 years or in adulthood. • Who have any suggestion of a focal onset on history, examination or electroencephalography (EEG). • In whom seizures continue in spite of first-line medication. Routine brain MRI may well reveal an underlying cause, such as neoplasia. This should be performed within 4 weeks of presentation (NICE epilepsy guidelines1). The principal role of MRI in epilepsy however, is in the definition of structural abnormalities that underlie seizure activity. In patients with drug-resistant epilepsy, excision of such a lesion may be curative or may improve seizure control. MR spectroscopy is sometimes used to assess concentrations of cerebral metabolites and some neurotransmitters non-invasively. Scintigraphy This can be used as a further means of imaging in potentially preoperative MRI-negative cases. PET may provide data on regional cerebral blood flow, glucose metabolism, and the binding of specific ligands to receptors.
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Information for the radiologist • Symptoms and signs at presentation and current seizure activity. • Response to medical treatment. • If surgery is being considered.
(a)
(b) Fig. 10.13 A 30-year-old patient who presented with 3 seizures over a week. a) Axial contrast-enhance CT demonstrating a mixed attenuation lesion anterior left insula region. b) Coronal T1 post gadolinium image confirming this high-grade tumour with extensive oedema.
Reference 1 NICE. The epilepsies: the diagnosis and management of the epilepsies in adults and children in primary and secondary care. London: NICE, 2004.
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Head and neck differential diagnosis Bare orbit 170 Orbital calcification 170 Absent or hypoplastic paranasal sinuses 170 Opacification of maxillary antrum 170 Nasopharyngeal mass 170
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Bare orbit • Neurofibromatosis. • Metastatic disease. • Meningioma.
Orbital calcification • • • • •
Cataract. Retinoblastoma. Previous infection. Meningioma. Vascular calcification.
Absent or hypoplastic paranasal sinuses • • • • •
Congenital. Down’s syndrome. Kartagener’s syndrome. Paget’s disease. Fibrous dysplasia.
Opacification of maxillary antrum • • • • • •
Trauma. Infection. Malignancy. Fibrous dysplasia. Wegener’s granulomatosis. Dentigerous/mucous retention cyst.
Nasopharyngeal mass • Normal adenoids (esp. in children). • Mass lesions: • Nasopharyngeal cancer. • Lymphoma. • Angiofibroma. • Rhabdomyosarcoma. • Trauma. • Infection.
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Head and neck presenting syndromes Neck lumps 172 Hoarse voice 173 Dysphagia 174
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Neck lumps Differential depends on position: • Superficial (within skin): • Lipoma. • Sebaceous cyst. • Anterior triangle: • Lymph nodes (reactive or malignant). • Branchial cleft cyst. • Carotid body tumour. • Aneurysm. • Vascular malformation. • Midline: • Thyroid mass. • Thyroglossal duct cyst. • Laryngocoele. • Dermoid cyst. • Submandibular: • Lymph node. • Salivary gland infection. • Salivary gland tumour. • Sialolithiasis. • Posterior triangle: • Commonly lymph nodes. • Cervical rib. • Pharyngeal pouch (rare).
Imaging Ultrasound Usual first-line modality for assessment of palpable lumps, it allows accurate localization and characterization, as well as guiding biopsy if required. CT Useful in assessment of deeper structures, especially if infection and abscess formation are being considered. MRI Gives better soft tissue characterization than CT and should be used if suspecting metastatic disease from a nasopharyngeal and oropharyngeal primary. Fluoroscopy Sialography (contrast injection in the salivary gland ducts) gives accurate images of the glandular structure, as well as stones or strictures in the duct. Nuclear medicine PET-CT is used in the assessment of malignant lymph nodes with no known primary. Scintigraphy is also used in cases of thyroid and parathyroid enlargement.
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Hoarse voice The commonest causes of a sudden change in voice quality are infection, laryngitis, pharyngitis, and epiglottitis. Imaging plays a role in cases where direct inspection raises the possibility of tumours on the vocal cord, or recurrent laryngeal nerve palsy. The left recurrent laryngeal nerve passes into the mediastinum and loops under the aortic arch before coming back up into the neck, and so is potentially involved in diseases affecting the left side of the mediastinum. The right recurrent laryngeal nerve doesn’t come so far down, looping under the brachiocephalic artery, and so is less often affected.
Imaging Plain film CXR may show a lung or mediastinal mass to account for a laryngeal nerve palsy. Ultrasound Little role, but can be used to search for and characterize lymph nodes if appropriate. CT Used to stage laryngeal tumours, and to investigate the course of the laryngeal nerve, if vocal cord palsy has been diagnosed at endoscopy.
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Dysphagia Defined as difficulty swallowing, and may be due to problems in the pharynx or lower down in the oesophagus. Pharyngeal causes are often associated with odynophagia (painful swallowing). Remember gradually progressive dysphagia over several weeks, especially in the elderly, is strongly suggestive of malignancy. Differential includes: • Infection: • Tonsillitis. • Pharyngeal abscess (quinsy). • Oesophagitis. • Foreign body. • Pharyngeal pouch. • Malignancy: • Pharyngeal. • Oesophageal. • Gastric. • Benign oesophageal stricture. • Globus hystericus.
Imaging Plain film Lateral soft tissue view of the neck may reveal a foreign body (if radioopaque such as a chicken bone) or widening of the pervertebral space in cases of pharyngeal abscess. CXR will show oesophageal dilatation if significant, or possibly a hiatus hernia. Fluoroscopy Contrast swallow studies are used to assess the swallowing mechanism, as well as the structure of the pharynx and oesophagus. Can also demonstrate aspiration and reflux. CT To assess the neck and mediastinal structures, especially in cases of extrinsic compression. MRI Used to assess pharyngeal malignancy. Nuclear medicine PET-CT has an increasing role in the staging of many tumours, including oesophageal.
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Head and neck conditions Nasopharyngeal tumours 176 Oropharyngeal tumours 178 Laryngeal carcinoma 180 Thyroid nodules and masses 182 Primary hyperparathyroidism 184 Hypoparathyroidism 186 Sinus disease 188 Parotid and submandibular salivary glands: infection 190 Sialolithiasis 192 Parotid and submandibular salivary glands: tumours 194 Branchial cleft cysts 196
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Nasopharyngeal tumours Most nasopharyngeal malignancies are squamous cell cancers and they most commonly occur in the lateral wall of nasopharynx within the fossa of Rosenmüller (area around the ostium of Eustachian tube). Men are more frequently affected than women. Risk factors include Epstein–Barr virus, exposure to smoke or to chemical pollutants, and ingestion of salted fish. Imaging has an important role in staging as well as planning the treatment of nasopharyngeal cancers.
Clinical presentation The most common presenting symptom is a neck mass due to metastatic lymphadenopathy. Other symptoms include epistaxis, nasal obstruction, hearing loss due to blockage of Eustachian tube, and cranial nerve palsies due to skull base invasion.
T-staging • Tis: carcinoma in situ. • T1: tumour confined to nasopharynx. • T2: tumour extends to oropharynx and/or nasal fossa: • T2a: without parapharyngeal extension. • T2b: with parapharyngeal extension. • T3: tumour invades bony structures and/or paranasal sinuses. • T4: tumour with intracranial extension and/or involvement of cranial nerves, infratemporal fossa, hypopharynx, orbit, or masticator space.
Imaging MRI The preferred imaging modality for the evaluation of the primary tumour due to better soft tissue contrast and multiplanar capability compared to other modalities (Fig. 13.1). Ultrasound Cannot accurately assess the primary tumour but is useful in the assessment of cervical nodal disease, and can also guide biopsy of suspicious lymph nodes. CT Useful in the evaluation of nodal involvement. The primary draining lymph nodes from nasopharyngeal cancer are the retropharyngeal nodes. CT also detects early bony cortical invasion. Nuclear medicine • PET-CT is used in the assessment of residual and recurrent disease following treatment, looking for metastases, and searching for primary lesions in cases of unexplained nodal disease. • Biopsy is the only definite way to establish the diagnosis.
Information for the radiologist • Detailed clinical history and result of endoscopy if already performed.
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(a)
(b) Fig. 13.1 a) Axial MR image with gadolinium enhancement revealing a large nasopharyngeal tumour involving the skull base and spreading into the infra temporal fossae on both sides. b) Sagittal MR image of the same patient as (a).
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Oropharyngeal tumours 90% of oropharyngeal malignancies are squamous cell cancers. Men are affected three times as frequently as women. Risk factors include heavy smoking, heavy alcohol consumption, chewing tobacco and betel (common in parts of Asia), and human papillomavirus (HPV) infection. The oropharynx consists of: • Pharyngeal wall between nasopharynx and pharyngoepiglottic fold. • Soft palate. • Tonsils. • Base of tongue.
Clinical presentation Patients usually present with dysphagia, persisting sore throat or otalgia but advanced cases may present with trismus or severe pain.
T-staging • • • • •
Tis: carcinoma in situ. T1: tumour ≤2cm in greatest dimension. T2: tumour >2cm but ≤4cm in greatest dimension. T3: tumour >4cm in greatest dimension. T4a: tumour invades any of these: larynx, deep/extrinsic muscle of the tongue, medial pterygoid, hard palate, and mandible. • T4b: tumour invades any of these: lateral pterygoid muscle, pterygoid plates, lateral nasopharynx, skull base, or encase the carotid artery.
Imaging Imaging has an important role in defining the extent and accurately staging oropharyngeal tumours. Imaging is also used to monitor response to treatment and can influence treatment choice in certain cases. Ultrasound Cannot accurately assess the primary tumour but is useful in the assessment of cervical nodal disease, and can guide biopsy of suspicious lymph nodes. CT Useful in evaluating the extent of the primary tumour as well as nodal involvement. It is widely available, has the advantage of speed, and allows chest imaging at the same time (now part of standard staging protocols). MRI Superior in the assessment of soft tissue spread, perineural extension, and osseous involvement, particularly if dental amalgam is present (Fig. 13.2). Nuclear medicine PET-CT is used in assessing recurrent disease and may have a role in cases of nodal disease with an unknown primary.
Information for the radiologist Detailed clinical history and result of endoscopy if already performed.
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(a)
(b) Fig. 13.2 a) Axial MR image revealing a large tumour in the left side of the tongue spreading into the space behind the mandible. b) Gadolinium-enhanced MR image from the same patient as (a) revealing necrosis in the left-sided neck nodes. Biopsy confirmed squamous cell carcinoma.
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Laryngeal carcinoma Carcinomas of the larynx are classified into supraglottic, glottic (true vocal cords) or subglottic depending on the site of origin. 95% are squamous cell carcinomas. Risk factors include smoking and alcohol use. Glottic carcinoma is the commonest form of laryngeal cancer. It presents early with hoarseness and has the best prognosis. Supraglottic carcinoma arises above the true cords. Normally presents later, with non-specific symptoms such as dysphagia, odynophagia, and otalgia. Patients may present with a neck mass due to lymphatic spread. Subglottic carcinoma is the least common. It arises from the undersurface of the vocal cord and usually presents with hoarseness. The subglottis is a difficult area to assess endoscopically and imaging is especially important.
Imaging Ultrasound Cannot accurately assess the primary tumour but is useful in the assessment of cervical nodal disease, and can also guide biopsy of suspicious lymph nodes. CT The role of imaging is to assess deep and submucosal spread that is blind to the endoscope (Fig. 13.3). CT allows better assessment of the laryngeal cartilages and suffers fewer motion (swallowing and breathing) artefacts than MRI. Regional lymphadenopathy can be assessed and staging is completed with CT of the chest. Coronal reformatted images are useful for assessing the craniocaudal extent of supraglottic tumours and to visualize the superior margin of the true vocal cord. MRI Better soft tissue contrast resolution than CT. Useful when cartilage invasion is equivocal on CT, and to assess tumour spread out from the larynx. Nuclear medicine PET-CT is used in initial staging and to assess response to therapy.
Information for the radiologist • Smoking history. • Endoscopic and clinical findings. • If recurrence is suspected, details of previous surgery and radiotherapy are very important.
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Fig. 13.3 CT image at the level of the hyoid revealing a soft tissue mass in the left side of the larynx with necrotic nodes in the right neck. Biopsy confirmed squamous cell carcinoma.
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Thyroid nodules and masses Thyroid nodules are very common, being found in 4–8% of adults on palpation and in 10–41% by means of ultrasound. The majority are benign, due to cysts, adenomas, or colloid nodules. Although uncommon thyroid cancer may also present as a solitary nodule. Investigation is therefore directed towards discriminating the small percentage of malignant nodules from the large number of benign ones. Thyroid cancer is classified into papillary (commonest accounting for 60% of cases), follicular, medullary, and anaplastic. Papillary and medullary carcinomas have a high incidence of spread to local lymph nodes whereas follicular carcinoma tends to show early haematogenous spread to lung and bone. Lymphoma and metastases may also present as a thyroid mass.
Presentation Most patients with thyroid nodules are asymptomatic. A haemorrhagic cyst may present with sudden onset of pain and swelling in the neck. The presentation of thyroid cancer is variable and depends on the histological type. Neck pain from local invasion, dysphasia, or symptoms of distant metastases can all occur.
Imaging Plain film • Limited role but CXR may detect tracheal deviation from retrosternal goitre, mediastinal lymph nodes, and lung metastases. • Plain radiographs can show metastases in bone, which are usually lytic and expansile. Ultrasound The most sensitive method for diagnosing intrathyroid lesions. Features of a benign nodule are a well-defined margin, large cystic component, peripheral ‘egg shell’ calcification, and lack of internal vascularity. Features of a malignant lesion include hypoechogenicity, ill-defined margin, fine internal calcification, heterogeneity, and internal vascularity. There is much overlap in these features so fine needle aspiration is often required (Figs. 13.4 and 13.5). CT Not sensitive in depicting intrathyroid lesions; however, it is useful for evaluating lymphadenopathy, local tumour extension, and distant metastases from thyroid cancer. It may also be useful for intrathoracic goitre to show its location and extent, to distinguish it from other causes of superior mediastinal mass and assess tracheal compromise. MRI Has a limited role in characterizing thyroid nodules, although it is effective in the diagnosis of cervical lymph node metastases and in staging thyroid lymphoma. Scintigraphy Used to determine the functional status of nodules. Nodules may be ‘cold’, ‘warm’, or ‘hot’, depending on the uptake of tracer compared with normal thyroid. Thyroid cancers concentrate less radio-iodine than normal
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thyroid tissue and hence appear ‘cold’. Although only 10–25% of cold nodules contain tumour (benign causes include multinodular goitre, focal thyroiditis, and cysts) this finding always requires further assessment. Technetium-99m pertechnetate is most often used. Gallium-67 scintigraphy is a useful adjunct as thyroid lymphoma is the only thyroid malignancy that takes up this radionuclide.
Information for the radiologist • The presenting symptoms and signs. • The results of thyroid function tests.
Fig. 13.4 Ultrasound image of the right lobe of thyroid revealing an echo free cyst. There are no features of malignancy and the patient can be reassured.
Fig. 13.5 Ultrasound image from a different patient revealing a well defined solid nodule in the thyroid isthmus. Ultrasound-guided fine needle aspiration revealed no malignancy.
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Primary hyperparathyroidism Hyperparathyroidism (HPT) may be primary, secondary, or tertiary. Primary HPT is caused by inappropriate excess of parathyroid hormone (PTH) resulting in hypercalcaemia and hypophosphataemia. It is usually due to a single adenoma, occasionally hyperplasia, and rarely carcinoma. The treatment of a symptomatic parathyroid adenoma is surgical removal. Preoperative localization is the most common indication for imaging of the parathyroid glands. Ectopic glands are seen in 20% of patients and may be found anywhere from the level of the hyoid bone down to the aortic root.
Clinical presentation Most patients with primary HPT present with mild hypercalcaemia discovered incidentally. More severe hypercalcaemia produces nephrolithiasis, abdominal pain, nausea, constipation, pancreatitis, bone pain, arthralgia, and mental disturbance (‘stones, bones, groans, and psychic overtones’).
Imaging Imaging studies should be performed only after the diagnosis of primary HPT is established on the basis of biochemical findings. Plain film Radiographs are useful in documenting the effects of HPT upon the bony skeleton, but not the underlying cause. Classic plain film signs include subperiosteal bone resorption on the radial aspects of the phalanges and holes in the bone known as ‘Brown’s tumours’. Ultrasound This is the initial investigation of choice. Normal-sized parathyroid glands are usually not visualized. Parathyroid adenomas appear as discrete, oval, hypoechoic masses, usually posterior to the thyroid gland although their position can be very variable. Ultrasound-guided fine needle aspiration may be performed to allow cytological confirmation or PTH-assay. Nuclear medicine (Fig.13.6) Scintigraphy is the preferred method of examination if ultrasound does not locate the adenoma. Parathyroids and thyroid take up isotopes at different rates and a subtraction method can be used to localize the adenoma. CT May be used to detect an ectopic adenoma inaccessible to ultrasound. MRI Has better sensitivity than CT for localizing ectopic mediastinal glands.
Information for the radiologist • Relevant previous surgical history (i.e. of the head/neck/chest). • Previous or current history of malignancy. • Any known co-existing thyroid nodules.
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Fig. 13.6 Screen shot images from a SPECT scan showing an ectopic parathyroid adenoma localized to the superior mediastinum. (Image courtesy of Dr Andy Scarsbrook.)
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Hypoparathyroidism Hypoparathyroidism may be congenital or acquired, due to accidental removal of the parathyroid glands during thyroid surgery or their ablation by radio-iodine therapy. Autoimmune disease is a less common cause. Biochemical findings are of hypocalcaemia and hyperphosphataemia.
Clinical presentation The clinical features of hypoparathyroidism are due to hypocalcaemia. Symptoms include numbness around the mouth and extremities, followed by cramps, tetany (carpopedal spasm), convulsions, and death if untreated.
Imaging The skeleton is usually normal. The principal radiological manifestation is calcification of the basal ganglia and areas of the cerebrum and cerebellum (seen on CT/MRI). In pseudohypoparathyroidism (same biochemical findings as hypoparathyroidism but with lack of response to parathormone), affected individuals are short in stature with short metacarpals, metatarsals, and phalanges. The 4th and 5th metacarpals in particular are affected. The teeth are hypoplastic with defective enamel. These changes are best demonstrated on plain radiographs.
Information for the radiologist Relevant previous surgical history (i.e. of the head/neck/chest).
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Fig. 13.7 Axial CT showing dense calcification of the basal ganglia due to hypoparathyroidism. There is also an acute right subdural haematoma and artefact from a cochlear implant on the left. Image courtesy of Dr. Daniel Warren.
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Sinus disease Inflammatory sinus disease may be acute or chronic. Each sinus has its own pattern of mucociliary clearance. Altering normal secretions, ciliary action, or the patency of ostia will result in pathology. Frontal, anterior ethmoid, and maxillary sinuses all drain into the middle meatus. The region where they drain is the osteomeatal complex (OMC). The sphenoid and posterior ethmoid sinuses drain into the superior meatus. Disease at the OMC causes obstruction of drainage pathways and is a major cause of recurrent acute or chronic sinusitis.
Presentation Acute sinusitis is often due to secondary bacterial infection following viral upper respiratory tract infection. This results in overproduction of mucus by the inflamed mucosa. Clinically there may be headache, sinus pain, fever, and nasal discharge. Chronic rhinosinusitis clinically represents recurrent acute sinusitis or a prolonged acute episode refractory to treatment. Other disease entities such as sinonasal polyposis and mucocoeles are often associated with chronic rhinosinusitis.
Imaging Plain film Popular historically but are no longer widely used. CT The mainstay of modern sinus imaging. Mucosal thickening, polyps, and air fluid levels are all clearly seen, as well as potential complications of acute sinusitis: • Osteomyelitis: rare with the use of antibiotics. • Intracranial abscess: spread of infection from the frontal or sphenoid sinuses may give rise to cerebral abscess or subdural empyema. • Orbital cellulitis: usually follows ethmoid sinusitis and may result in orbital abscess formation. CT of the sinuses is used in chronic rhinosinusitis prior to functional endoscopic sinus surgery (FESS) to examine the extent of sinus disease, carefully assess the OMC, and note any anatomical variants (Fig. 13.8). CT can also assess nasal septal deviation and the presence of sinonasal polyposis—which is seen as soft tissue in the nasal cavity, usually arising from the ethmoid sinuses (Fig. 13.9). MRI MRI lacks the bony detail of CT but is useful in cases of sinus malignancy.
Information for the radiologist • Full clinical details including features to suggest a complication of sinusitis. • Plans for surgery.
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Fig. 13.8 Coronal reformat of a CT through the sinuses, revealing normal anatomy. Note the 2 osteomeatal complexes through which the maxillary sinuses drain into the nose.
Fig. 13.9 Coronal reformat of a CT revealing extensive nasal and maxillary polyp formation. Note also the previous surgery attempting to improve the sinus drainage by widening the osteomeatal complexes.
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Parotid and submandibular salivary glands: infection Mumps is the commonest cause of acute parotitis but rarely requires imaging. Staphylococcal and streptococcal infections develop in debilitated, dehydrated patients with poor oral hygiene. These patients present with tender swollen glands and systemic signs of infection. Pus may be seen discharging from the parotid duct orifice.
Imaging Ultrasound Allows assessment of the gland texture, any underlying duct abnormality, calculi, and abscess formation. Also will demonstrate associated nodes, and allow aspiration if appropriate but it may be difficult to fully assess depth of infection. CT (Fig. 13.10) Will show a diffusely swollen gland with inflammatory stranding in the surrounding fat. If an abscess is present this will appear as an area of absent enhancement (dark area within bright gland) or irregular ring enhancement. CT gives a good overall view of the neck and better assessment of deeper structures than ultrasound. Also useful for detecting stones and gas formation. MRI Not so good at detecting calculi or gas as CT and little advantage in the acute setting.
Information for the radiologist • History, especially risk factors such as previous stones, radiotherapy, etc. • Blood results.
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Fig. 13.10 Coronal reformat of a CT from a patient with suppurative infection originating in the salivary glands, now extending throughout the tissue planes of the neck and into the mediastinum.
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Sialolithiasis Salivary gland calculi form as the result of stasis of saliva or infection. They are more common in the submandibular gland (80%) because the saliva is more viscous and the ducts take an uphill course. Patients present with pain and swelling of the affected gland, related to meals. Occasionally the stone may be palpated in the floor of mouth. Sialolithiasis may lead to chronic sclerosing sialadenitis with fibrosis and atrophy of the gland.
Imaging Plain film The majority of stones are radio-opaque on plain films. Ultrasound Useful initial investigation. Calculi can be identified as an echogenic focus within the gland and associated duct dilatation will also be seen (Fig. 13.11). CT Unenhanced scans will demonstrate the stone and then IV contrast can be given to demonstrate any intraglandular abscess. MRI Thin section T2 MRI (MR sialography) is less satisfactory for identifying small stones because of signal voids. Sialography Contrast injected into the relevant duct opening in the mouth can identify stones and secondary duct dilatation (Fig. 13.12).
Information for the radiologist Appropriate history and clinical findings.
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Fig. 13.11 Ultrasound of the submandibular gland reveals a large stone in the duct. Note the dense acoustic shadowing behind it.
(a)
(b)
Fig. 13.12 a) Control film from a submandibular sialogram reveals a well-defined calculus in the position of the duct. b) Following an injection of iodinated contrast the stone is confirmed to lie within the duct.
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Parotid and submandibular salivary glands: tumours 80% of salivary gland tumours arise in the parotid gland. Pleomorphic adenomas are the most common (50%). Patients present with a painless slow growing lump/swelling within the affected gland. Warthin’s tumours make up around 10% of benign parotid tumours and are usually found in the parotid tail, occasionally bilaterally. Carcinomas are less common than benign lesions. Pain, rapid growth, and neurological involvement (facial nerve palsy) all suggest malignancy.
Imaging Ultrasound Suspected salivary gland tumours should be investigated by ultrasound in the first instance. Fine needle aspiration can also be performed, but crosssectional imaging will often be required in addition. CT Findings depend on the particular tumour, but in general CT allows easy assessment of all the major salivary glands, tumour extent and depth, and regional nodal involvement (Fig. 13.13). MRI Allows more accurate assessment of the facial nerve than CT in cases of parotid malignancy and therefore useful prior to surgery (Fig. 13.14).
Information for the radiologist • History and clinical findings are important for deciding the most appropriate investigations. • Contraindications to IV contrast or MRI will help guide imaging. • If recurrence of malignant disease is suspected then a detailed history of previous surgery and radiotherapy is necessary to interpret difficult imaging findings.
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Fig. 13.13 Axial CT image reveals a large, partly necrotic tumour arising from the left parotid. This was a squamous carcinoma.
Fig. 13.14 Heavily T2-weighted (with fat saturation) MR image of the left parotid reveals a well defined homogeneous lesion in the gland. Biopsy confirmed a benign cyst.
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Branchial cleft cysts These benign neck cysts usually appear before the age of 30. The 1st branchial cleft develops into the external auditory canal. The 2nd, 3rd, and 4th branchial clefts merge to form the sinus of His, which will normally involute. When a branchial cleft does not properly involute, a branchial cleft cyst forms. See Table 13.1 for classification.
Clinical presentation Branchial cysts are usually asymptomatic, but they may become painful due to secondary infection. Alternatively, they may present with local mass effect such as respiratory compromise. Fine needle aspiration yields pus-like fluid that is rich in cholesterol crystals. The treatment is surgical excision. However, recurrence rates of up to 20% are reported.
Imaging Ultrasound Useful initial investigation of any neck mass (Fig. 13.15a). Although ultrasound can confirm the position and cystic nature of the mass, it does not adequately evaluate the extent and depth of neck lesions. MRI This more reliably confirms the cystic nature of the mass and provides precise definition of the extent of the lesion and its relationship to surrounding structures (Fig. 13.15b). MRI is especially advantageous for type I 1st branchial cleft cysts and for parapharyngeal masses that may be 2nd branchial cleft cysts. Wall thickness and enhancement following IV contrast administration varies according to the severity of any associated infective/inflammatory process. CT Branchial cleft cysts appear as well-defined, ovoid, fluid-filled lesions.
Information for the radiologist • Symptoms and signs at presentation. • Presence of raised inflammatory markers (WCC, CRP). • Any clinical suspicion of malignancy (metastatic squamous cell carcinoma to cervical nodes may mimic a branchial cleft cyst).
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(a)
(b) Fig. 13.15 a) Ultrasound image from a 19-year-old man with a painless swelling in the right neck reveals a well-defined cystic lesion. b) Coronal T2c weighted MR scan from the same patient as (a) confirms the anatomical position and benign characteristics of a 2nd branchial cleft cyst.
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Table 13.1 Types of branchial cleft cysts 1st
Type I: located near the external auditory canal, most commonly inferior and posterior to the tragus. May also be in the parotid gland or at the angle of the mandible Type II: associated with submandibular gland or found in the anterior triangle of the neck
2nd
Accounts for 95% of branchial anomalies May present anywhere from the skin of the lateral neck, between the internal and external carotid arteries, and into the palatine tonsil Most commonly seen along the anterior border of the upper 1/3 of sternocleidomastoid
3rd
Rare Characteristically located deep to sternocleidomastoid within the posterior triangle of the neck
4th
Extremely rare Arise in various locations, paralleling the course of the recurrent laryngeal nerve, including the thyroid gland and mediastinum
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Genitourinary differential diagnosis Bladder filling defects 200 Renal calcification 200 Testicular lesions 200 Adrenal calcification 201 Dilated ureter 201
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Bladder filling defects • Blood clot. • Tumour (transitional cell carcinoma (TCC) adult and rhabdomyosarcoma child). • Calculus. • Infection/debris. • Prostate. • Foreign body. • Ureterocoele.
Renal calcification • Calculi. • Dystrophic calcification due to localized disease: • Infection. • Carcinoma. • Aneurysm. • Nephrocalcinosis: • Medullary: hyperparathyroidism, renal tubular acidosis, medullary sponge kidney etc. • Cortical: acute cortical necrosis, chronic glomerulonephritis, chronic transplant rejection.
Testicular lesions Testicular masses • Germ cell tumours (GCTs): • Seminoma: most common testicular tumour in adult. • Embryonal carcinoma: 20–25% GCT. • Choriocarcinoma: rare. • Teratoma: 5–10%. • Non-germ cell tumours: usually benign. • Lymphoma or leukaemia: may relapse in testis. • Metastases: kidney, prostate, bronchus, pancreas. • Orchitis.
Extra testicular masses • • • • • • •
Varicocoele. Hydrocoele. Hernia. Testicular torsion. Epididymitis. Epididymal cyst. Scrotal trauma/oedema.
Causes of hydrocoele • Congenital. • Infantile. • Secondary to trauma, infection, torsion, or neoplasm.
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Adrenal calcification • • • • • • •
Cyst. Carcinoma: irregular, punctate calcifications. Addison’s disease. Ganglioneuroma. Inflammatory: TB/histoplasmosis. Phaeochromocytoma. Ureterocoele.
Dilated ureter Obstruction Within the lumen: • Calculus. • Blood clot. • Sloughed papilla. In the wall: • Oedema secondary to a stone. • Tumour. • TB. • Post surgical. • Ureterocoele. • Megaureter. Outside the wall: • Retroperitoneal fibrosis. • Carcinoma (cervix, prostate, bladder, rectum). • Retrocaval ureter. • Pregnancy/postpartum. Other: • VUR. • Infection.
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Chapter 15
Genitourinary presenting syndromes Acute pelvic pain 204 Chronic pelvic pain 206 Acute renal failure 207 Haematuria 208 Hydronephrosis 209 Hypertension 210 Intermenstrual bleeding 211 Postmenopausal bleeding 212 Testicular pain 213
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Acute pelvic pain Acute pelvic pain is a common presenting complaint, especially in women. However, in addition to gynaecological causes there are many other aetiologies:
Causes Gynaecological • Ectopic pregnancy. • Ovarian cyst: haemorrhage, torsion. • Hydrosalpinx. • Mittelschmertz. Urological • Renal colic. • Cystitis. • Acute urinary retention. Surgical • Acute appendicitis. • Diverticulitis. • Localized perforation. • Inflammatory bowel disease (although likely to be previous episodes). • Ruptured iliac aneurysm. • Strangulated inguinal/femoral hernia.
Clinical presentation The exact presentation depends on the underlying aetiology. A thorough history and examination should be conducted in order to establish the most appropriate differential diagnosis. Symptoms • Dysuria. • Frequency. • Haematuria. • Signs of sepsis: pyrexia, night sweats. • Menorrhagia. • Amenorrhea. • Increased bowel frequency.
Imaging Pelvic ultrasound Transabdominal (TA) ± transvaginal (TV) will aid in diagnosing an ectopic pregnancy or ovarian problems. However, a normal ultrasound in a patient with a positive pregnancy test does not rule out an ectopic. • Ectopic pregnancy. • Ovarian cyst ± haemorrhage. • Dilated fallopian tubes, consistent with hydro-/pyosalpinx. Renal ultrasound • Hydronephrosis. • Urinary calculi.
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CT KUB (kidneys, ureters, and bladder) This is used to look for urinary tract calculi. CT abdomen and pelvis • For surgical causes of acute pelvic pain, a CT of the abdomen and pelvis is performed. • Evaluation of signs of free fluid, gas, and inflammation of the bowel.
Information for the radiologist • • • • •
Pregnancy test result. Most likely diagnosis—to aid in appropriate imaging choice. Creatinine level if IV contrast is to be given. Previous history of urinary calculi or tumours. History of previous operations.
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Chronic pelvic pain This is a common problem among women aged 20–50 years; accounting for 20–40% of all gynaecological outpatient appointments. The main differential diagnoses include: • Endometriosis. • Adenomyosis. • Pelvic inflammatory disease. • Pelvic congestion. • Fibroids. • Adhesions. • Irritable bowel syndrome. • Interstitial cystitis.
Clinical presentation Considerable overlap of symptoms in these patients: • Dysmenorrhoea. • Dyspareunia. • Menorrhagia. • Fertility problems. • Dysuria.
Imaging Ultrasound: TA ± TV • Features of endometriosis, e.g. endometrial cysts may be demonstrated. Smaller endometrial deposits are not easily identified on ultrasound. • Adenomyosis. • Uterine fibroid. • Pelvic varices may be demonstrated using Doppler ultrasound. Pelvic MRI MR is superior to CT in the investigation of pelvic organs. • Endometriosis, in particular endometrial deposits, are identified better on MR than using ultrasound. • Ovarian cysts/masses can be characterized. • The blood supply to fibroids can be assessed for suitability for embolization techniques. Hysterosalpingography This uses a radio-opaque dye to test the patency of the uterine cavity and fallopian tubes. Venography This can be used to diagnose and treat pelvic varices in pelvic congestion syndrome. Angiography This technique can be used to embolize and therefore cut off the blood supply to treat uterine fibroids.
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Acute renal failure Deterioration in renal function over hours/days, patient is likely to be systemically unwell and is usually oliguric. Determining causation is vital to direct management. • Pre-renal cause: decreased renal perfusion, commonly dehydration. Consider vascular compromise: renal artery stenosis or renal vein thrombosis. • Renal cause: acute tubular necrosis (ATN), glomerulonephritis, or interstitial nephritis. Precipitating factors include circulatory collapse, nephrotoxins, medications, and vasculitis. • Post renal cause: obstructive uropathy. At the renal pelvis or ureteric level the cause may be intraluminal (stones, pus, haematoma), mural (TCC or inflammatory) or extra-mural (intra-abdominal/pelvic malignancy or retroperitoneal fibrosis). Pathology in the bladder or prostate is also a common cause of obstruction. The initial assessment is to measure the urine output with catheterization if required.
Imaging Ultrasound To assess for hydronephrosis—if acute this is evidence of obstruction. A cause should be sought such as the presence of a mass or calculi. Renal parenchyma, size and contour of the kidney is important to determine the presence of chronic atrophy. CT Caution required for the administration of IV contrast with pre-scan optimal rehydration mandatory. Quoting absolute creatinine levels as a contraindication to IV contrast is a topic for debate and it is probably unhelpful as risk:benefit assessment is required on a case-by-case basis. Post-scan haemofiltration is possible. NCCT scanning is excellent to demonstrate stone disease and upstream obstruction can be observed, replacing the IVU. Nephrostomy Percutaneous insertion of a drain through the renal parenchyma into a dilated calyx, with the tip in the renal pelvis. Indications: obstructive uropathy to alleviate renal failure and preserve renal function, or to release infection. Septic obstruction or a single functioning obstructed kidney should prompt discussion for on-call intervention.
Information for the radiologist • • • • • •
Onset of the renal failure, creatinine levels. What is the urine output? Is there bladder outflow obstruction? Lateralizing signs to suggest a kidney or ureteric cause? Is there a single functioning kidney? Is the patient septic?
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Haematuria Can be frank (visible to inspection) or microscopic (detected on dip test). Always requires investigation which can be done on an urgent outpatient basis if it is the sole presenting feature. Complications can include retention secondary to clots.
Causes • • • • • • • • •
Suspect bladder and prostate pathology first. Stone disease. Malignancy (RCC, TCC, prostate). Infection. Trauma. Renal parenchymal disease. Urethral pathology. March (microtrauma to red cells, seen in runners). Haematological paroxysmal nocturnal haemoglobinuria (PNH), bleeding diathesis.
Investigation • • • •
Urine culture and cytology. Flexible cystoscopy. Renal ultrasound + IVU complete the standard work. Retrograde ureterograms/uretroscopy can be performed in theatre by urologists if diagnostic uncertainty remains regarding the upper tracts. • CT-KUB ± CT-IVU are gaining popularity for the investigation of difficult cases/replacing IVU.
Imaging Ultrasound Look for calculi which cast shadows. Assess for renal masses either parenchymal (RCC) or collecting system (TCC). Look for dilatation of the pelvicalyceal system or more focal dilatation of a calyx both of which can indicate obstruction from TCC or stone disease. The bladder should be imaged and a volume obtained post micturition in men to assess for prostatic obstruction. Note ultrasound is no match for cystoscopy in the identification of bladder pathology. IVU Declining use as CT urography gains popularity. Contraindicated in renal failure and caution required in patients taking metformin (stop for 48 hours pre test). CT-KUB/CTU CT-KUB is a NCCT covering the kidneys, ureters, and bladder and is excellent for demonstrating stone disease. CTU adds a second scan after two boluses of IV contrast 6–8 minutes apart giving excretion and nephrogram phase imaging. It is excellent for demonstrating malignancy.
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Hydronephrosis Dilatation of the renal pelvis, due to urinary tract obstruction. Common causes are: • Luminal: calculus, blood clot, tumour. • Wall: ureteric/urethral stricture, congenital bladder neck obstruction/ urethral valve, neuropathic bladder. • Extrinsic: aortic aneurysm, prostatic obstruction, pelvic tumours, diverticulitis.
Clinical presentation • Loin pain: may be provoked by anything that increases urine volume. • Complete anuria: suggestive of bilateral obstruction or complete obstruction if single kidney. • Infection: malaise, fever, and septicaemia.
Imaging Ultrasound Once hydronephrosis is established try to find cause: • Identification of renal or bladder calculi. • Allows assessment of bladder emptying, therefore signs of bladder outlet obstruction may be identified. • If a nephrostomy is required (tube in kidney to relieve the obstruction) ultrasound is used to guide the tube into the dilated calyx. CTU • Used to look for presence of urinary tract calcification. • IV contrast is given to assess renal excretion and to look for evidence of any filling defects along the urinary tract (stones or tumours). MRI This technique can be used in patients where there is a contraindication to IV contrast. Nuclear medicine • Used (more commonly in children) in obstructive uropathies to look at uptake and excretion. • Differential function is calculated.
Information for the radiologist • Relevant past medical history, i.e. history of malignancy. Urea and creatinine levels, recent ‘trend’ in blood results. • Clotting if an intervention is necessary.
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Hypertension Common medical condition characterized by consistently elevated blood pressure. Defined as >140mmHg systolic or 90mmHg diastolic. Hypertension can be either primary or secondary; primary hypertension essentially means that no cause can be found, accounting for 85–90% of cases. There are many causes of secondary hypertension including chronic renal failure, renal artery stenosis, and tumours such as adrenal adenomas or phaeochromocytomas.
Clinical presentation Early hypertension is usually asymptomatic but as the condition progresses symptoms include dizziness, nausea and vomiting and visual disturbance. High blood pressure is however a risk factor for many other medical conditions such as stroke, heart attack, aortic aneurysm, cardiac failure and renal failure.
Imaging Plain film On a chest X-ray hypertension may manifest with cardiomegaly ± signs of heart failure. In children and young adults coarctation of the aorta may cause hypertension—in this case the classic finding is notching of the inferior surface of the upper ribs. Ultrasound Renal ultrasound may be used to look for renal parenchymal disease such as polycystic kidney disease or chronic glomerulonephritis. Renal artery Dopplers can also be measured to assess for signs of renal artery stenosis; however, MRA is more sensitive. Renal tumours such as renal cell carcinoma and Wilms tumour may also rarely cause hypertension. CT Tumours causing hypertension, e.g. a phaeochromocytoma, may be picked up on CT. The extent of any atherosclerosis can be assessed, and complications such as aortic aneurysm can be seen. Angiography Fibromuscular dysplasia is a cause of renovascular hypertension in the young, particularly women. On angiography the classic finding displayed in the renal arteries is described as the ‘string of beads sign’. This represents areas of stenoses interspersed with small aneurysms. Echocardiography An echo may show signs of LVH as a result of prolonged systemic hypertension.
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Intermenstrual bleeding Vaginal bleeding (other than postcoital bleeding) which occurs at any time during the menstrual cycle which is not during normal menstruation.
Causes Many potential causes of intermenstrual bleeding (IMB), some easily diagnosed, others may require imaging. Causes include: Hormones • Combined oral contraceptive pill (COCP): either in too low dose or in combination with an enzyme inducing drug. • Progesterone-only pill. • Contraceptive depot injections. • Intrauterine devices. • Emergency contraception. • Tamoxifen. Tumours (benign and malignant) • Gynaecological cancers including vaginal, cervical, and endometrial cancer. • Ovarian tumours (usually oestrogen secreting tumours). • Endometrial and cervical polyps. • Fibroids. Others • Following smear test or treatment to the cervix. • Caesarean section scars. • Drugs altering clotting parameters, e.g. anticoagulants, SSRIs, corticosteroids. • Adenomyosis (ectopic endometrial tissue in the myometrium).
Investigation guidelines NICE guidelines for patients presenting with IMB are as follows: • A mandatory full pelvic examination, including cervical speculum examination. • Do not wait for a smear result or delay due to a previous negative smear result—refer immediately where there is clinical suspicion. • Consider urgent referral for women with persistent IMB but negative examination findings.
Imaging Imaging may not be needed in all cases. Ultrasound First-line investigation. Usually TA and TV pelvic ultrasound will be performed. The endometrial thickness is measured and images of the ovaries, uterus and adnexae are obtained. CT CT is usually a second-line test if ultrasound has been difficult or nonconclusive. It will also be used in staging of cancers such as ovarian cancer. MRI Will usually be performed if any abnormality is detected on ultrasound. Pelvic masses are usually characterized using MRI.
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Postmenopausal bleeding Endometrial or vaginal atrophy is the most common cause but more sinister causes such as carcinoma must be ruled out. Other causes include trauma or anticoagulants, hormone replacement therapy, endometrial or cervical polyps, and endometrial hyperplasia.
Imaging • Gynaecological examination (hysteroscopy) is used in conjunction with imaging. Ultrasound TA imaging is performed first to gain images of the pelvis and both kidneys. TV ultrasound is used to measure endometrial thickness, generally the greater the endometrial thickness the greater the chance of sinister pathology. In postmenopausal women, the endometrium should be thinner than in premenopausal women. A thickness >5mm is thought to be abnormal. Using this figure of 5mm will mean that sometimes pathology is overlooked, however in cases where clinical suspicion is high then hysteroscopy is also carried out. CT CT would not usually be used a first line of investigation. Used in staging of cancers. Intervention such as omental biopsy in cases of ovarian cancer can be performed under CT or ultrasound guidance. MRI MRI is useful in characterizing pelvic masses that have been seen on either ultrasound or CT. The MRI characteristics of a mass can be assessed on different sequences to characterize it accurately. For example, endometrial cancer has slightly lower signal intensity than normal endometrium on T2 imaging; there may also be disruption of the junctional zone. A definitive diagnosis is of course only made by endometrial biopsy.
Information for the radiologist Any previous gynaecological surgery should be noted on the request, e.g. hysterectomy and BSO. Any current or previous hormone treatment should also be noted.
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Testicular pain Causes • • • • • • • • • •
Testicular torsion. Torsion of the appendix of the testis (hydatid of Morgagni). Trauma. Testicular tumour (due to haemorrhage within). Epididymitis. Orchitis. Varicocoele. Inguinal hernia. Segmental testicular infarction. Renal colic (radiated pain).
Imaging Ultrasound The diagnosis of suspected testicular torsion should be made clinically and investigated by surgical exploration without delay. Only in equivocal cases should imaging be considered (see b Testicular torsion, p. 254 for further details). Ultrasound using a high-frequency probe is the first-line imaging resource for assessing the scrotum and its contents. It provides highresolution information of both the testes and related structures. In experienced hands, it can reliably differentiate between the conditions listed earlier and it is cheap, readily available, and quick to perform. Historically, radionuclide scanning was used in equivocal cases of testicular torsion to assess testicular blood flow. However, it has become a somewhat redundant technique since the advent of ultrasound.
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Genitourinary conditions Bladder and urothelial cancer 216 Renal cell cancer 218 Testicular cancer 220 Prostate cancer 222 Cervical cancer 224 Endometrial cancer 226 Ovarian masses 228 Ovarian cancer 230 Adrenal masses 232 Benign renal masses 234 Pyelonephrosis 236 Renal tract calculi 238 Renal transplant dysfunction 240 Vesico-ureteric reflux 242 Ectopic pregnancy 244 Endometriosis 246 Ovarian torsion 248 Pelvic inflammatory disease 250 Epididymitis 252 Testicular torsion 254
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Bladder and urothelial cancer • Bladder cancer is the commonest malignancy of the urinary tract; 90% are transitional cell carcinomas (TCCs). • Risk factors: smoking, aromatic chemical exposure. Other primaries of the renal tract include squamous cell cancer (associated with repeated infection or stone disease) and adenocarcinoma. • 30% multifocal, usually with additional sites within the bladder although between 1–5% may have proximal disease. Metachronous disease evolves in up to 25% of cases.
Clinical presentation • Commonly haematuria although UTI, dysuria, pyuria, and flank pain account for a significant number. • Initial investigations include FBC, U&Es, urine cytology, and cystoscopy.
TNM staging • • • • • • • • • •
Tis: carcinoma in situ. T1: subepithelial invasion. T2: muscularis invasion. T3: perivesical invasion. T4: invades side wall, adjacent organ or into perinephric fat for renal TCC. N0: no node spread. N1: single node 5cm or multiple nodes >2cm. M1: distant metastasis.
Imaging Ultrasound (Fig. 16.1a) First-line investigation. Echogenic lesions are seen in the bladder lumen, arising from the wall. May see hydronephrosis. Limitations include evaluation of wall invasion and detection of lymph nodes. CT (Fig. 16.1b) CT urography used to demonstrate the upper tracts where initial investigations have not demonstrated pathology, as an alternative to the conventional approach of retrograde pyelograms/uretroscopy performed by urologists in theatre. TCC appears as a filling defect in the contrast. CT can assess tumour size, local invasion, and hydronephrosis. Staging CT is performed if malignancy is known, looking for nodal and metastatic disease. MRI MRI scan can be used for local staging in the pelvis but not as a routine investigation in most units. Scintigraphy Demonstrates areas of increased osteoblastic activity associated with metastatic deposits.
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Information for the radiologist • Presenting symptoms including findings which suggest metastases. • Biopsy and cytology results. • Surgical history including previous sites of disease, resections and therapy regimens. • Renal function if having CT.
(a)
(b) Fig. 16.1 a) Ultrasound and b) axial CT showing a filling defect within the right side of the bladder (arrows), in a patient with biopsy proven tumour.
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Renal cell cancer • 8th most common malignancy, the peak incidence is in 6th and 7th decades. Male: female = 2:1. • Associations: long-term dialysis, von Hippel–Lindau syndrome, obesity, smoking, exposure to petroleum products, heavy metals, and asbestos. • Survival is directly linked to stage at presentation with a >50% 5-year survival for stage II disease and >70% for stage I disease. Metachronous metastases develop in up to 30% predicted by involvement of local lymph nodes. Local recurrence in 5%.
Clinical presentation • Haematuria, flank pain, and a palpable mass are the classical features; however, only around 10% will have all 3. • Systemic symptoms include lethargy and weight loss. Calcium and erythropoietin levels should be checked.
Robson’s staging system • • • • • • •
I: tumour confined to kidney (large or small). II: spread to perinephric fat but within Gerotas fascia. IIIA: spread to renal vein or vena cava. IIIB: spread to local lymph nodes. IIIC: spread to both venous system and local lymph nodes. IVA: spread to adjacent organs (excludes ipsilateral adrenal). IVB: presence of distant metastases.
Imaging Ultrasound Performed as a first-line investigation for haematuria. Excellent detection of renal lesions including solid and cystic masses. Provides Doppler blood flow information regarding invasion of the renal vein or IVC. CT (Fig. 16.2) Performed pre- and post-IV contrast for lesion analysis, in particular the presence of enhancement. If a suspected malignant lesion is present a full chest, abdomen/pelvis staging scan should be performed to assess local stage, lymph-nodes, vascular invasion, and metastases. Bone scintigraphy Performed to assess for skeletal metastatic disease in the presence of clinical suspicion. Metastases show high tracer activity due to increased osteoblastic activity. Metastases on plain film are typically lucent and expansile.
Information for the radiologist • Presenting symptoms, relevant medical history and test results including previous imaging. • Sites of clinically suspected metastases should be highlighted.
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Fig. 16.2 Coronal CT image showing solid mass arising from the right kidney (arrow), renal cell cancer, in contrast to the well-rounded, low attenuation simple cysts in the left kidney.
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Testicular cancer • 95% are germ cell tumours, typical affect men aged 15–45 years. Divided into non-seminomatous (NSGCT) and seminomatous germ cell tumours. • NSGCT include teratomas, affect a younger age, 10–20 years. Seminomas peak incidence 30–40 years. • Tumour markers include A-fetoprotein (AFP), hCG (mainly NSGCT), and lactic dehydrogenase (LDH) (both). • In the UK 1 in 500 men. • Risk factors: cryptorchidism, genetic predisposition and malignancy in the contralateral testis. • Treatment is dependent on pathology and stage with NSGCT responding better to chemotherapy and seminomas to radiotherapy.
Clinical presentation Usually with a hard lump in the testis. Pain and tenderness are less common and usually mild.
TNM staging • • • • • • • • • •
Tis: intratubular neoplasia. T1: tumour not invading lymphatics, vessels or tunica vaginalis. T2: vascular/lymphatic invasion and/or invasion of tunica vaginalis. T3: invades spermatic cord. T4: invades scrotum. N1: regional nodes (ipsilateral aorto-caval) 50 years, genetic predisposition, familial/racial preponderance Afro-Caribbean >Caucasian >Asian. • Distinction made between clinical prostate cancer and microscopic, up to 30% men >50 years thought to harbour the disease, most of which will never become apparent.
Clinical presentation Symptoms of prostatism, haematuria, urinary obstruction, or metastatic disease; however, an increasing number present with an abnormal digital rectal examination (DRE) or an elevated prostate specific antigen (PSA). PSA screening is not performed in the UK at present but has gained popularity in the USA and some of Europe.
TNM staging • • • • • • • • • • • • •
T1a: on histology only from a TURP malignancy in 5% of sample. T1c: identified on histology from a TRUS biopsy sample. T2a: less than half of one lobe (DRE or imaging). T2b: more than half of one lobe (DRE or imaging). T2c: involves both lobes (DRE or imaging). T3a: extra-capsular extension. T3b: extra-capsular extension involves the seminal vesicles. T4: invades local structures other than seminal vesicles. N1: one or more regional nodes involved. M1a: distant (outside the pelvis) lymph nodes involved. M1b: bone metastases. M1c: non-bone metastases.
Imaging Plain film and bone scintigraphy Useful to determine the presence of bone metastases. Often sclerotic on plain film. ‘Hot’ osteoblastic reaction is seen on bone scanning. Request if symptomatic or PSA markedly elevated. Ultrasound: trans-rectal ultrasound guided biopsy (TRUS) The accepted method of obtaining tissue for diagnosis in patients with a raised PSA and suspicion of prostate cancer. Non-targeted ‘random’ samples are aimed at the peripheral zone of the gland, due to the known preponderance of disease here (>70%). CT Staging CT advised if PSA >20, T ≥3, Gleason grade ≥8 or symptoms suggest metastatic spread. Looking for upper tract obstruction, lymphadenopathy, and metastases.
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MRI (Fig. 16.4) Used for local staging to predict spread through the prostatic capsule— important to determine operative or conservative management. It can predict lymph node involvement and bone metastases but is limited by the field of view. Some centres advocate full spinal acquisitions to stage for bone metastases in clinical/biochemically appropriate cases.
Information for the radiologist PSA level and presence of symptoms suggestive of metastases.
Fig. 16.4 Axial MRI showing a bulky prostate, with a low signal intensity area within the peripheral aspect of the right prostate (arrow). The posterior margin of the prostate is blurred, in keeping with early T3 disease.
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Cervical cancer • 3rd most common malignancy worldwide, average age at diagnosis is 50 years. • 90% squamous carcinomas, from squamocolumnar junction; 10% adenocarcinomas/adenosquamous carcinomas, arising from glandular elements within the endocervical canal.
Clinical presentation Vaginal bleeding or discharge. Pain suggests more advanced disease. May be asymptomatic if screen detected.
Staging (see Table 16.1) Table 16.1 Staging of cervical cancer FIGO stage
MRI features
0: carcinoma in situ
Normal
IA: microscopic invasive
Normal
IB1: clinically visible tumour 4cm IIA: invasion of tumour to upper 2/3 vagina, no parametrial invasion
Loss of integrity of low signal vaginal wall on T2-weighted sequences
IIB: parametrial invasion but not to pelvic side wall
Dark cervical stromal ring completely replaced by intermediate signal tumour
IIIA: tumour extends to lower 1/3 vagina, not to pelvic side wall
Disruption of the vaginal wall extends to the lower 1/3
IIIB: extension to pelvic side wall or hydronephrosis
Tumour extends to within 1cm of the pelvic side walls or there is ureteric dilatation due to obstruction from the tumour
IVA: bladder or rectal mucosa invaded by tumour
Bladder or rectal wall on T2-weighted images is breached
IVB: distant metastases
Tumour outside the true pelvis
Imaging Preoperative staging to determine the size and extent of tumour, lymph node status and presence of distant metastases.
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Ultrasound Transrectal ± transvaginal scanning may determine tumour size and extent. The limited field of view reduces assessment of bulky tumours and lymph nodes. CT Useful in advanced disease but not accurate in staging early stage tumours. Assessment of local complications, e.g. hydronephrosis, lymphadenopathy, and detection of distant metastases. MRI (Fig. 16.5) Most accurate staging method preoperatively, determining tumour size, volume, extent, and nodal status with an overall accuracy of 86–90%. It is also useful to monitor treatment response. FDG-PET Main advantage is in detection of lymph node metastases in the pelvis and retroperitoneum. It is also useful in the detection of recurrence of cervical tumour.
Information for the radiologist Accurate clinical and EUA findings.
Fig. 16.5 Sagittal MRI showing exophytic tumour (arrow) arising from the cervix, in a patient with a tumour of the cervix.
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Endometrial cancer • One of the most common female pelvic malignancies, usually adenocarcinoma. Less common histological types include serous papillary carcinoma, clear cell carcinoma and undifferentiated carcinoma, which are more aggressive. • Predominantly occurs in postmenopausal women. • Risk factors: hypertension, obesity, diabetes mellitus, late menopause, long-term tamoxifen treatment for breast cancer, a personal or family history of breast or ovarian cancer, and a family history of endometrial or breast cancer, hereditary non-polyposis colorectal cancer.
Clinical presentation Postmenopausal vaginal bleeding or vaginal discharge.
Staging (see Table 16.2) Table 16.2 Staging of endometrial cancer FIGO stage
MRI features
IA: confined to endometrium
Junctional zone intact, smooth interface between endometrium and myometrium
IB: 50% invasion into myometrum
Tumour signal intensity extends into outer half of myometrium. Serosal surface of myometrium maintained
IIA: extension into endocervix
Tumour signal extends into internal os and widens endocervical canal. Cervical stroma intact
IIB: cervical stromal invasion
Dark signal of cervical stroma interrupted by hyperintense tumour signal
IIIA: spread outside uterus into adnexa
Serosal surface disrupted, direct extension into ovaries or discrete ovarian metastases
IIIB: vaginal involvement
Dark T2-weighted signal of vaginal wall invaded by hyperintense tumour
IIIC: lymph node involvement
LN metastases suggested if >1cm in short axis. Also morphological features such as altered signal of LN, irregular margins, extension outside LN capsule
IVA: bladder or rectum involvement
Loss of T2-weighted dark signal of walls of bladder and rectum
IVB
Distant metastases
Imaging Ultrasound (Fig. 16.6) TV ultrasound is the first-line test. Look for: • Endometrial thickness of >4mm: detects 95% of endometrial carcinoma (may be thicker if on hormone replacement therapy/tamoxifen). • Abnormal endometrium is heterogeneous, hyperechoic, and irregular.
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• If there is bleeding, a biopsy is required if the endometrial thickness measures >4mm. • Endometrial thickness >8mm: with or without bleeding requires biopsy. • Hysterosonography is a useful adjunct to conventional TV ultrasound, although not widely available. 5ml saline is introduced into the uterine cavity using a catheter, this helps the TV ultrasound to delineate causes such as submucosal myomas or polyps. CT May demonstrate pelvic disease and para-aortic lymph node involvement. Not good at local staging. MRI Used to locally stage endometrial carcinoma pre-operatively, looking for disruption of normal zonal anatomy and to plan treatment.
Information for the radiologist Any salient clinical findings and tumour grade and histology if known.
Fig. 16.6 Sagittal T2-weighted image through the midline of the pelvis, showing a bulky mass arising from the endometrium of the upper uterus. This was found to be endometrial adenocarcinoma at histopathology, following hysterectomy.
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Ovarian masses There is a broad spectrum of masses, ranging from physiological cysts to malignant tumours. It is beyond the scope of this chapter to detail every ovarian mass. Instead the broad concepts of imaging and characterization will be described. (See also b Ovarian cancer, p. 230.)
Clinical presentation Depends on the underlying pathology. Abdominal pain may be a presenting feature if there has been an acute event, such as haemorrhage into a cyst. Ovarian cancer tends to present late with abdominal distention.
Imaging • Confirm the presence and characteristics of a pelvic mass and determine its organ of origin. • In cases of malignant tumours, imaging is used for: • Preoperative staging. • Assessment of response to treatment. • Detection of recurrence in the context of clinical deterioration or worsening tumour markers. • Guiding percutaneous biopsies/aspiration of ascites. Ultrasound First-line investigation. There is much overlap between benign and malignant tumours, although certain features may suggest a particular tumour type. It may be necessary to repeat an ultrasound after a 6-week interval to establish whether the ovarian mass identified is physiological and potentially will resolve. CT (Fig. 16.7) May detect incidental ovarian masses, due to the widespread use of this modality. Cysts associated with the ovary that are >3.5cm should be followed up with ultrasound in 6 weeks to ensure resolution. MRI Provides excellent tissue contrast and high spatial resolution. MRI may be used if the mass: • Is large (>10cm). • Is complex or indeterminate on ultrasound. MRI can accurately determine malignant from benign features, e.g.: • Intralesional fat in keeping with a teratoma. • Altered blood in an endometrioma. • Fibrous tissue, observed in ovarian fibromas or brenners tumours.
Information for the radiologist History and examination, tumour markers such as CA-125.
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Fig. 16.7 Axial CT showing a mixed attenuation mass within the left adnexa. This contains fat (dark) and calcified teeth (arrow) in keeping with a dermoid tumour.
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Ovarian cancer • 5th leading cause of death from cancer in women. • >90% epithelial, arising from epithelium ovary/tube. Rarer types include germ cell tumour or sex cord/stromal tumours. • Risk increases with age and decreases with pregnancy. Associated with BRCA1 and BRCA2 gene mutations.
Clinical presentation Often non-specific symptoms, such as abdominal pain, mass, bloating. Late presentations include leg oedema due to pelvic vein pressures from pelvic mass. Associated with raised CA-125.
Imaging Ultrasound (Fig. 16.8a) First-line investigation to assess the ovaries. Ultrasound findings suggestive of a malignant tumour: • Ovarian cyst >10cm. • Thick internal septa >3mm. • Solid component in a cystic mass. • Colour Doppler flow in the solid elements. • Presence of ascites. • Presence of peritoneal nodules. CT (Fig. 16.8b) CT features suggestive of a malignant ovarian tumour include: • The presence of bilateral adnexal masses. • Mixed solid and cystic components. • Enhancement of solid components after IV contrast. • Necrosis in a solid tumour. • Irregular, thick septae >3mm within a cystic mass. • Papillary nodules within a cystic mass. • Presence of lymphadenopathy. • Invasion into other pelvic organs. • Ascites. • Serosal or peritoneal deposits. MRI The following MR features are suggestive of malignancy: • The presence of solid components that have early strong uptake of gadolinium. • Papillary projections: one of the most significant indicators of malignancy. • Secondary malignant features such as ascites, invasion of pelvic organs, and enlarged lymph nodes.
Information for the radiologist History and clinical examination findings, tumour markers.
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(a)
(b) Fig. 16.8 a) Ultrasound showing complex ovarian cyst in a patient with raised CA-125. The cyst contains a mural nodule (arrows) and debris. This was an ovarian cancer. b) Axial CT in a patient with bilateral adnexal masses (not shown). The CT shows ascites, and a thick ‘cake’ of omental disease (arrow). This was due to advanced ovarian cancer.
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Adrenal masses • Common incidental finding 81% of abdominal CT exams. • Non-functioning lesions are benign or malignant. Benign lesions include adenoma, myelolipoma, and haemorrhage. Malignant lesions may be primary or secondary. Functioning adrenal tumours may be: • Aldosterone secreting tumour. • Phaeochromocytoma. • Cushing’s syndrome.
Clinical presentation Majority asymptomatic. Metastatic lesions may be discovered as part of a staging scan. Commonest metastasis to the adrenal glands is from lung cancer followed by breast in women and renal cell carcinoma in men, but even in patients with known cancer, an adrenal lesion found on imaging has only a 26–37% chance of malignancy.1 Phaeochromocytoma presents with headache, sweating, flushing, and palpitations, and are bilateral 3cm are more likely to be malignant than those 4 is indicative of metastatic disease.
Information for the radiologist Any symptoms or history of malignancy.
Reference 1 Boland GW, Goldberg MA, Lee MJ, et al. Indeterminate adrenal mass in patients with cancer: Evaluation at PET with 2-(F-18)-flouro-2 deoxy-D glucose. Radiology 1995; 194:131–4.
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(a)
(b) Fig. 16.9 a) Non-enhanced axial CT showing fat attenuation nodule within the left adrenal gland, in keeping with a lipid-rich adenoma. b) Coronal MRI showing enhancing, solid mass arising from the left adrenal gland (arrow) found to be a phaeochromocytoma.
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Benign renal masses Often an incidental finding. Role of the radiologist is to decide if the lesion is benign, requires follow-up, or is malignant.
Clinical presentation Asymptomatic or local symptoms such as flank pain or retroperitoneal haemorrhage. Cysts Described using the Bosniak classification system. Class I and II cysts are best imaged with ultrasound, CT is to be used as a problem solver, and MRI to follow-up more complex cases. • Bosniak class 1 cysts: referred to as ‘simple cysts’: thin wall, near water density. Often multiple, usually of no consequence unless associated with polycystic kidney disease. • Bosniak class 2 cysts: this group contains: non-enhancing hyperdense cysts (haemorrhagic) 1 of the features of class 2 cysts or numerous septa, also hyperdense cysts >3cm. • Bosniak class 3 cysts: indeterminate lesions—cysts with evidence of wall thickening, mild nodularity, coarse calcification, septal enhancement. Require consideration for surgical resection. • Bosniak class 4 cysts: cystic carcinoma. Enhancing thick wall with soft tissue components. Enhancement generally considered as an increase in attenuation of >10 Hounsfield (CT density) units after contrast. Managed surgically. Angiomyolipoma (renal hamartoma) Contain fat, blood vessels, and connective tissue. If >4cm have increased risk of retroperitoneal haemorrhage. Usually appear bright on ultrasound. Can be safely diagnosed on CT (thin slice) and MR scanning (T1 and opposed phase) by demonstrating fat within the lesion. Abscess Can extend into the retroperitoneum. CT gives best demonstration of size and extent.
Imaging Start with ultrasound, use cross-sectional imaging (CT) as a problem solver (Fig. 16.10). Consider radiation dose if lesions are to be followed up. MRI can help in complex cases and is ideal for following-up patients with multiple lesions at risk of malignant transformation such as in Von-Hippel–Lindau syndrome.
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Fig. 16.10 Coronal CT in a patient with right-sided angiomyolipoma (arrows). The CT shows a mass containing fatty (dark) and soft tissue elements (lighter septations). In view of its large size, this was embolized.
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Pyelonephrosis Any condition affecting the renal pelvis; however, often used interchangeably with acute pyelonephritis which is a clinical diagnosis. Chronic pyelonephritis is typically atrophic kidneys following repeated infection/ obstruction, usually related to vesico-ureteric reflux. • Acute pyelonephritis: defined as flank pain, bacteriuria, and pyrexia. 85% caused by ascending UTI. 15% from haematogenous spread. Risk factors include stone disease, diabetes, vesico-ureteric junction reflux, and pregnancy. The role of imaging is to identify obstruction, elucidate causation, and detect complications such as abscess formation. • Emphysematous pyelonephritis: seen with severe infection in diabetics often in an older age group; thankfully rare. There is renal parenchymal gas and destruction, gas can spread in perinephric space and collecting system. NCCT is advised. Prognosis is poor. • Renal tuberculosis: infection via haematogenous route following pulmonary TB, often in immunocompromised. Half will have an abnormal CXR. Presentation is with haematuria, flank pain, sterile pyuria (it is difficult to culture TB, at least 3 samples advised). Pathological changes include destruction of the papilla, strictures, intrarenal cavitations, abscess formation, fistulas, and calcification. Disease progression can descend the ureters into the bladder, prostate, and seminal vesicles however this is rare. Imaging is with CT, CTU or IVU. • Xanthogranulomatous pyelonephritis: chronic inflammatory reaction following repeated infections usually with Proteus and is associated with stone disease. Can be focal or diffuse. Imaging demonstrates low density filling of the pelvicalyceal system and ureters. • Papillary necrosis: ischaemic sloughing of the papilla, causes include analgesic NSAID abuse, sickle cell disease, diabetes, and repeated infection. Detached papilla can be seen as filling defects in the collecting system best demonstrated on IVU or CT-IVU.
Imaging Ultrasound is the initial test to identify obstruction and can show pelvicalyceal pathology/calculi. CT provides extra information regarding causation, extent of disease, and extra renal complications (Fig. 16.11). CT-IVU can assess renal function, pelvicalyceal and ureteric pathologies demonstrated as filling defects within excreted contrast in the collecting systems.
Information for the radiologist Signs and symptoms and suspected clinical diagnosis.
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Fig. 16.11 Coronal CT showing ill-defined area of low attenuation (arrow) within the right kidney in a patient with pyelonephritis.
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Renal tract calculi • Peak incidence 20–55 years, with a male: female preponderance of 4:1. • Calculi form by crystallization of minerals in urine in the pelvicalyceal system. The most common are Ca2+ based. Associations include dehydration, UTI, metabolic abnormality, small bowel resection, and can be familial.
Clinical presentation • Loin pain radiating to the groin, which can cause nausea. • Haematuria (often microscopic) ± UTI.
Imaging Plain film 90% of stone are visible (Ca2+), (struvate (Mg2+ based) may not be). Plain films and IVU are becoming obsolete with the high sensitivity and availability of CT. Ultrasound Identifies hydronephrosis, indicative of obstruction. Calculi may be seen as the cause of obstruction. They are characteristic by the fact they cast an ‘acoustic shadow’; however, small calculi may not do this, and maybe missed. CT (Fig. 16.12) Gaining popularity is the CT ‘KUB’ or CT ‘stone chaser’. This is a non-IV contrast-enhanced CT scan covering the kidneys, ureters, and bladder. Performed prone with a full bladder. All stones with the exception of those produced by antiretroviral therapy are well seen. Upper tract obstruction may be seen. Alternative diagnosis may be found, such as appendicitis or diverticulitis. IVU Performed as a series of films. The acute protocol involves a control film and a film 10 minutes post-IV contrast, to identify obstruction. Percutaneous nephrolithotomy (PCNL) Performed in theatre by urologists with a radiologist. A retrograde ureterogram is performed to define the anatomy and the renal collecting system is punctured, like in a nephrostomy insertion, using ultrasound. The track is dilated and a device is inserted to perform stone removal.
Information for the radiologist Clinical signs, i.e. side of pain, haematuria, presence of sepsis.
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Fig. 16.12 Coronal CT showing left-sided hydronephrosis secondary to calculus within the upper left ureter (arrow).
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Renal transplant dysfunction Since the first successful renal transplant performed by Joseph Murray in 1954 between identical twins, transplant medicine has come a long way and with the advent of immunosuppressants, transplant surgery has become a hugely successful technique. The majority of renal transplants are ‘heterotopic’ which means that they are transplanted to the patient with the native kidneys still in situ. Usually the patients will have had chronic renal failure for some time and their native kidneys will be small and sometimes difficult to see in detail. The transplant kidney is usually placed in one of the iliac fossae, outside the peritoneum.
Imaging Ultrasound (Fig. 16.13) Ultrasound is used to assess dilatation of the pelvicalyceal system (PCS), interlobar artery flow, to guide biopsy and interventions such as drainage of collections and placement of nephrostomy tubes. Ultrasound is also useful in assessment of postoperative complications including: • Obstruction: a small degree of collecting system dilatation can be normal but persisting or worsening dilatation may indicate obstruction. This may be due to clot or debris within the ureter or as a result of an ischaemic-related stricture at the vesico-ureteric anastomosis. Nephrostomy under ultrasound guidance may be needed to relieve the obstruction in some circumstances. • Vascular occlusion: ultrasound is used to assess the flow in the main renal artery and veins and in the interlobar arteries. This is done using Doppler ultrasound. An absent renal vein flow may indicate total occlusion whereas a partial occlusion will manifest as reverse end diastolic flow in the arterial Doppler trace. • Rejection: non-specific ultrasound appearances include generalized oedema of the kidney and prominent pyramids. Clinical correlation is essential, and often biopsy is needed.
Information for the radiologist Transplant anatomy, renal function, and signs of sepsis.
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Fig. 16.13 Ultrasound showing hydronephrosis in a transplant kidney.
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Vesico-ureteric reflux • Predominantly affects children, with retrograde flow of urine from the bladder into ureters. • Primary: majority of cases. Failure of the one-way vesico-ureteric valve. • Secondary: to obstruction or poor functioning of the lower tract, e.g. in posterior urethral valves or neurogenic bladder. • May lead to renal scarring, hypertension, and chronic renal failure. • See Table 16.3 for classification. Table 16.3 International classification of radiographic grading of vesico-ureteric reflux Grade I
Ureter only
Grade II
Ureter, pelvis, and calyces; no dilatation, normal calyceal fornices
Grade III
Mild or moderate dilatation and/or tortuosity of the ureter and mild or moderate dilatation of the renal pelvis. None/slight blunting of the fornices
Grade IV
Moderate dilatation and/or tortuosity of the ureter and moderate dilatation of the renal pelvis and calyces. Complete obliteration of the sharp angle of the fornices but maintenance of the papillary impressions in the majority of calyces
Grade V
Gross dilatation and tortuosity of the ureter. Gross dilatation of the renal pelvis and calyces. The papillary impressions are no longer visible in the majority of calyces
Clinical presentation Usually diagnosed in investigation of antenatal hydronephrosis and paediatric UTI.
Imaging Ultrasound First-line investigation in UTI or suspected reflux, and for follow-up of antenatally diagnosed hydronephrosis. Local protocols vary, most units image children under 5 with a history of UTI, boys of any age with UTI, and children of any age with febrile UTI. Ultrasound features indicating vesico-ureteric reflux (VUR) include hydronephrosis, dilated distal ureters, small kidneys, renal scarring, and even demonstration of reflux in to the urinary tract during the examination. A normal ultrasound does not exclude VUR. MCUG (Fig. 16.14) Considered the gold standard investigation. Usually reserved for children under the age of 1 year due to the invasive nature of the procedure. Contrast is instilled into the bladder via a catheter and the ureters imaged during voiding for retrograde passage of contrast/dilatation. The urethra is also imaged in boys for signs of posterior urethral valves as a cause of VUR.
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Nuclear medicine Alternative technique to MCUG using 99m-pertechnetate instilled into the bladder. Advantage is reduced radiation dose but the limitations are lack of visualization of the urethral anatomy and difficulty in diagnosing minimal reflux as this may be obscured by bladder uptake. Technetium-99m dimercaptosuccinic acid (DMSA) is widely used in the investigation of VUR to diagnose and monitor renal scarring.
Information for the radiologist • History of proven UTI. • Previous imaging results including antenatal ultrasound scans.
Fig. 16.14 Coronal image from micturating cystogram showing contrast from the bladder refluxing up both ureters into the kidneys.
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Ectopic pregnancy • Ectopic pregnancy occurs when the fertilized egg implants outside of the endometrium of the uterus. • Incidence is 2% and the mortality rate is around 9–14%. • Risk factors include previous ectopic pregnancy, pelvic inflammatory disease, tubal surgery and the use of intrauterine devices.
Clinical presentation Abdominal pain and vaginal spotting following a period of amenorrhea. Indirect signs of ruptured ectopic are hypovolaemic shock, and shoulder tip pain due to diaphragmatic irritation. Pain may decrease after rupture.
Imaging Imaging should only be performed in stable patients. Initial evaluation of ectopic pregnancy should include a TV ultrasound (Fig. 16.15) in conjunction with a serum BhCG level. If the features of a normal pregnancy are not identified at a certain BhCG level, then close scrutiny for an ectopic pregnancy required (Table 16.4). Table 16.4 Correlation of BhCG, gestational age, and TVUS findings BhCG level (mIU/ml)
Gestational age (weeks)
Gestational sac
2000
4.5
Yolk sac
7000
5
Fetal pole
11000
5–6
Fetal heart beat
25000
5–6
Ultrasound 95% of ectopic pregnancies are tubal. Findings include: • An adnexal mass: size of mass, the presence of a gestational sac, a fetal pole, heart beat, and a yolk sac. • Pregnancy in a non-specific adnexal mass. • Pelvic fluid: look in the pouch of Douglas and right posterior subhepatic space. • The endometrium which may be normal or there may be a pseudogestation sac. MRI Problem solving modality to confirm or better define suspected ectopic pregnancy. Looking for: • An extrauterine gestational sac. • Fresh haematoma. • Tubal wall enhancement post contrast, due to increased vascularity following implantation.
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Information for the radiologist • Salient history and examination findings. • Last menstrual period important. • BhCG level if known.
Fig. 16.15 Image from a TV ultrasound showing a complex mass (indicated by callipers) inseparable from the right ovary. This was confirmed at surgery to be a tubal ectopic pregnancy, and the patient underwent a salpingo-oophorectomy.
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Endometriosis This is the presence of endometrial glands and stroma outside the uterine cavity and musculature. Ectopic endometrial material responds to hormonal stimuli causing cyclical haemorrhage. Common sites for endometrial deposits include the ovaries and pelvic peritoneum. Deep endometriosis describes endometriosis that infiltrates the peritoneum >5mm. These deposits are found in the subperitoneal pelvic space, the uterosacral ligaments, rectovaginal septum, and also in the bladder and bowel wall.
Clinical presentation Many patients are asymptomatic. It commonly presents with infertility or pelvic pain.
Imaging Ultrasound and MRI are the most useful tests. Occasionally the diagnosis may be unsuspected, and suggests following other imaging, such as barium enema showing endometrial serosal deposits on the bowel wall, typically at the rectosigmoid. Ultrasound • Endometriomas (‘chocolate cysts’) appear as complex cystic ovarian mass with homogeneous low level echoes and a thick wall (Fig. 16.16). • Hydrosalpinx maybe present. • Assessment of superficial peritoneal deposits, ovarian foci and deep endometriosis is less accurate with ultrasound. MRI • Typical MRI features of endometriomas include high signal intensity on T1-weighted sequences due to blood products in the cyst. There may be layering of fluid within the cyst due to blood products of different ages. • Features of deep endometriosis depend on whether it is infiltrative small implants, visceral implants, or solid deep lesions in the posterior cul-de-sac. Secondary complications of adhesions, such as bowel obstruction may be seen.
Information for the radiologist Detailed clinical symptoms and examination findings will help the radiologist identify endometriotic deposits accurately particularly when the deposits are small and subtle.
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Fig. 16.16 Ultrasound showing endometrioma within the right ovary.
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Ovarian torsion • The abnormal rotation of the ovary on its vascular pedicle, compromising the venous and arterial blood supply to the ovary. • Predisposing factors include: ovarian cyst (>5cm) or cystic neoplasm, cystic ovaries associated with ovarian hyperstimulation syndrome and polycystic ovaries. • Initially the venous outflow and lymphatic drainage are compromised, with maintenance of arterial inflow. The ovary enlarges and becomes oedematous causing arterial thrombosis, leading to ovarian ischaemia and infarction. • Highest prevalence is in women of reproductive age. 17–20% of cases occur in pregnant women.
Clinical presentation Symptoms may be non-specific—lower abdominal pain, nausea and vomiting associated with tenderness/peritonism, ± a palpable mass. Pain may be intermittent.
Imaging Ultrasound First-line investigation. Both TA and TV ultrasound should be performed. • A unilateral enlarged ovary ± a coexistent ovarian mass. • Peripheral ovarian follicles (‘string of pearl’ sign) as the follicles are displaced by the oedematous stroma. • Free fluid in pelvis. • Arterial and venous blood flow can be maintained despite a twisted vascular pedicle; however, absence of blood flow is highly suggestive of the diagnosis. CT (Fig. 16.17a) May be performed prior to ultrasound, as CT is commonly used as the first-line investigation for non-specific abdominal and pelvic pain. • An adnexal mass which may be displaced to the midline. • Ascites or haemoperitoneum. • Reduced central enhancement of the ovary. • Haemorrhage and gas in the ovary if necrotic. • Stranding and inflammatory changes in the adjacent fat. MRI (Fig. 16.17b) May be required when pelvic ultrasound inconclusive.
Information for the radiologist • • • •
Last menstrual period—is the patient pregnant? Is there any relevant gynaecological history? Is the woman taking infertility drugs? Are there any other symptoms to suggest other diagnoses, e.g. diverticulitis, appendicitis?
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(a)
(b) Fig. 16.17 a) CT and b) MRI in a patient with left-sided ovarian torsion. The CT shows a bulky, high attenuation left ovary, in keeping with haemorrhage. MRI showing enlarged, low signal intensity infarcted left ovary (long arrow), showing no enhancement compared to the normal right ovary (short arrow).
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Pelvic inflammatory disease • Infection of the upper genital tract, commonly sexually transmitted Chlamydia trachomatis or Neisseria gonorrhoeae. Less commonly occurs as a result of secondary infection from appendicitis or diverticulitis. • Peak incidence rate is in women aged 20–24 years. Long-term sequelae include infertility, ectopic pregnancy, and chronic pain if left untreated.
Clinical presentation Abdominal pain, raised temperature, vaginal discharge, abdominal tenderness, cervical and adnexal tenderness.
Imaging Ultrasound (Fig. 16.18) TA and TV ultrasound are the first-line investigations, looking for: • An enlarged and indistinct uterus. Adjacent fat may be inflamed and of increased echogenicity. • Free fluid in the pouch of Douglas. • Evidence of salpingitis which occurs in the early stages of pelvic inflammatory disease (PID). • A tubo-ovarian complex/abscess. • Perihepatitis: Fitz–Hugh–Curtis syndrome occurs when inflammatory exudates spread to the liver via the right paracolic gutter from the pelvis, causing RUQ pain. CT This may be the first investigation if symptoms are non-specific. Advantages of CT over US are that firstly, it is easier to appreciate the effects of pelvic inflammation on adjacent structures, e.g. bowel ileus, hydroureter, or appendicitis. Secondly, subtle signs of inflammation are easier to appreciate on CT, e.g. there may be haziness in the pre-sacral fat, thickening of the uterosacral ligaments, peritoneal enhancement or periovarian stranding in adjacent fat. Classic features of PID are also appreciated on CT such as dilated fallopian tubes, adnexal abscesses, enlarged ovaries, and free fluid. MRI MRI has a higher sensitivity and specificity in depicting PID compared with TV ultrasound. However, ultrasound is a relatively low cost and more readily accessible compared to MRI. MRI should only be used in difficult cases as a problem solver.
Information for the radiologist Relevant history and examination findings.
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Fig. 16.18 Ultrasound showing dilated, fluid filled fallopian tube (arrow). The fluid is seen to contain debris.
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Epididymitis May be acute or chronic. Usually acute, secondary to infection, resolving with antibiotic therapy. The role of imaging is to confirm the diagnosis and exclude complications.
Clinical presentation • Acute epididymitis: presentation is with acute pain and scrotal inflammation. Secondary to ascending UTI, sexually transmitted infection, or haematogenous infection. Recent instrumentation can be a factor. Numerous bacteria are associated, e.g. Escherichia coli, Pseudomonas, gonorrhoea, Chlamydia, and TB. • Chronic epididymitis: pain and tenderness for >6 weeks, often unclear aetiology. Associations: previous infection, scrotal surgery, or systemic inflammatory conditions. Investigate for infection especially Chlamydia. Treatment is with antibiotics and anti-inflammatories. Role of imaging is limited. Investigations FBC (increased WCC) and urine sample. Chlamydia can be difficult to culture and may require prostatic massage or direct epididymal sampling. Differential diagnosis • Orchitis: if present without epididymitis is likely mumps. • Sperm granuloma (post vasectomy). • Torsion (younger age group). • Tumour: especially in young children an extra-testicular mass in the scrotum may represent a rhabdomyosarcoma.
Imaging Ultrasound (Fig. 16.19) Performed with a high-frequency probe. In acute epididymitis the entire epididymis is enlarged, occasionally only the head. The echogenicity is either low due to oedema or heterogeneous. Blood flow is mostly increased. Complications include scrotal abscesses. The collection should demonstrate increased through transmission of sound (picture looks brighter behind)—an important ultrasound imaging sign. Alternative pathology can be demonstrated such as tumour or orchitis. In chronic epididymitis the imaging can be normal or a more subtle swelling of the epididymis may be seen.
Information for the radiologist Clinical history, in particular any surgical procedures.
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Fig. 16.19 Ultrasound showing oedematous hyperaemic epididymitis in a patient with epididymitis.
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Testicular torsion • Male proximal interphalangeal joint (PIPJs), thumb carpometacarpal joints (CMCJs), metacarpophalangeal joints (MCPJs), and the trapezio-scaphoid joint. • Feet: similar to hand. • Hip: superior joint space narrowing at the maximum weight-bearing joint area. • Knee: medial compartment most commonly affected due to weight distribution. • Spine: apophyseal joints, narrowing of intervertebral disc spaces. • Sacroiliac joints (SIJs): contralateral SIJ to the arthritic hip joint. MRI This can be used as a specialist investigation to look for early loss of joint cartilage, usually in the hips or knees.
Information for the radiologist • Site, duration, and severity of patient’s symptoms. • Predisposing factors to OA, e.g. obesity, acromegaly, avascular necrosis, slipped upper femoral epiphyses, previous trauma, or joint infections.
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(a)
(b) Fig. 19.1 Images a) and b) show severe OA of the knee with marginal osteophytes, loss of joint cartilage, and subchondral sclerosis.
Reference 1 Roberts J, Burch TA. Osteoarthritis prevalence in adults by age, sex, race, and geographic area. Vital Health Stat 1. 1966; 11(15):1–27.
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Rheumatoid arthritis This is a chronic systemic disorder causing a bilateral symmetrical inflammatory joint disease. Affects women >men, usually aged between 40–60 at diagnosis. Synovial joints are affected with synovial hyperaemia and proliferation (pannus) leading to bone erosions and cartilage destruction.
Clinical presentation The American Rheumatism Association decree that at least 4 of the following criteria are required, lasting at least 6 weeks, for diagnosis:1 • Early morning joint stiffness, which lasts 1 hour before improvement. • Simultaneous joint swelling in at least 3 joints. • Symmetrical arthritis involving in particular the PIPJs, MCPJs, or wrist. • Subcutaneous nodules. • Positive rheumatoid factor (above 95th percentile). • Typical radiographic changes of erosions and periarticular osteopenia.
Imaging Plain film Appearances may be normal. Early signs include periarticular osteopenia, subcortical synovial cysts, soft tissue swelling, and widened joint spaces due to synovial inflammation. Later signs include erosions, reduction in joint space secondary to cartilage destruction, joint subluxation, ankylosis and loose bodies. • Hand (Fig. 19.2a): affects MCPJs and PIPJs >DIPJs. Characteristic deformities include: • Ulnar deviation at the wrist. • Ankylosis of the carpal bones. • Boutonniere: hyperflexion at PIPJ, hyperextension at DIPJ. • Swan-neck: hyperextension at PIPJ, hyperflexion at DIPJ. • Mallet finger: droopy distal phalanx. • Feet: similar appearances to the hands. • Cervical spine: erosions of the odontoid peg and atlanto-axial subluxation. • Shoulder: involves the glenohumeral and acromioclavicular joints (Fig. 19.2b). • Knees: bilateral and symmetrical. Osteoporosis and erosions. • Chest: pleural or pericardial effusions, rheumatoid nodules which may cavitate and occasionally lower zone fibrosis. Ultrasound May demonstrate synovitis, joint effusions and tendon rupture. MRI Demonstrates synovitis, erosive changes, and pannus.
Information for the radiologist • Distribution and duration of symptoms. • Rheumatoid factor if known.
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(a)
(b) Fig. 19.2 A 55-year-old patient with severe right hand and left shoulder deformity. a) Demonstrates severe erosive disease primarily affecting the radio-carpal, carpal and metacarpalphalangeal joints. b) Shows complete loss of the humeral head as well as severe erosive disease to the acromio-clavicular joint.
Reference 1 Arnett F, Edworthy S, Bloch DA, et al. The American Rheumatism Association 1987 revised criteria for the classification of rheumatoid arthritis. Arthritis Rheum 1987; 31(3):315–24.
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Crystal deposition • Gout: deposition of monosodium urate crystals in and around joints or in the urinary tract. Predominantly affects middle aged/elderly men. Serum uric acid is often raised. • Calcium pyrophosphate deposition disease (CPPD): deposition of calcium pyrophosphate crystals in and around joints. Commonly associated with gout. • Alkaptonuria: rare autosomal recessive disorder causing excess homogentisic acid deposition in connective tissues, cartilage and bone.
Clinical presentation • Gout: usually monoarticular and may be asymptomatic in the early stages. Acute presentations are with a hot, swollen, painful joint, typically the first MCPJ. Chronic presentations are with repeated bouts of arthritis in the same joint. Less common presentations are with urinary calculi (radiolucent), tendon rupture or paraesthesia due to nerve paralysis. • CPPD: presentation may be similar to gout (pseudogout), OA or rheumatoid arthritis. Can be monoarticular or polyarticular and most commonly affects the knees, wrist, MCPJs, and PIPJs. • Alkaptonuria: back pain, skin and sclera pigmentation, dark urine, heart failure, or renal failure.
Imaging Plain film In the early stages often normal. • Gout: affects feet >hands and small joints >large joints. Soft tissue swelling, ‘punched-out’ erosions with overhanging edges, subchondral cysts and soft tissue crystal deposition which may calcify (gouty tophi) (Fig. 19.3). • CPPD: resembles OA with osteophyte formation, joint space narrowing, subchondral cysts, and sclerosis. Cartilage calcification (chondrocalcinosis) is characteristic, especially around the knee, pubic symphysis, and triangular fibrocartilage of the wrist. • Alkaptonuria: calcification of intervertebral discs, vertebral ankylosis and osteophytosis. Early onset OA is also a feature. Ultrasound May identify soft tissue calcification, synovitis, nerve compression, tendon rupture or renal calculi. CT Used to identify radiolucent urinary calculi. MRI Not commonly used. Will show erosions, soft tissue calcification, synovitis and bony ankylosis.
Information for the radiologist • Site, duration and frequency of symptoms. • Serum urate if known.
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Fig. 19.3 Single foot radiograph taken after a 45-year-old presented with an exquisitely painful, red great toe with no history of preceding trauma. There is widespread degenerative change with multiple punched out para-articular erosions (arrow) and marked soft tissue swelling. These findings are typical for gout.
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Ankylosing spondylitis This is an autoimmune seronegative disease, affecting ligamentous insertions, synovial and cartilaginous joints. It causes a chronic arthritis eventually leading to bony ankylosis and enthesopathy, classically involving the spine, pelvis, proximal femur, and calcaneus.
Clinical presentation The typical patient is a young Caucasian adult male (15–35 years). They present with insidious onset of lower back pain and stiffness, usually worse in the mornings. As ankylosis progresses, the range of movement reduces. Complications include fractures, pulmonary fibrosis, and respiratory compromise. Other associations include aortic valve incompetence, iritis, and ulcerative colitis.
Imaging Plain film (Fig. 19.4a) These are good for monitoring progression. • SIJs: indistinct joint margins are followed by sclerosis and later ankylosis. Usually bilateral and symmetrical. • Spine: changes usually begin in the lumbar spine: • ‘Bamboo spine’ (flowing syndesmophytes on the AP radiograph). • Ossification of spinous ligaments. • Squaring of anterior vertebral end-plates (Romanus lesions). • ‘Shiny corner’ of vertebral bodies secondary to sclerosis. • Apophyseal erosions and ankylosis. • Disc calcification. • Kyphosis. • Atlanto-axial subluxation. • Hands: osteophytes, osteoporosis, joint space narrowing and erosions affecting the MCPJ, PIPJ, DIPJ’s. • Chest: upper lobe fibrosis, occasional bullae and cavitation. • Other: periostitic ‘whiskering’ at sites of ligamentous insertions, e.g. greater femoral trochanter, iliac crest, ischial tuberosity, calcaneum. CT HRCT chest may show upper lobe fibrosis, peripheral interstitial lung disease, and bronchiectasis. MRI (Fig. 19.4b) This has an expanding role in the early detection of ankylosing spondylitis. The earliest findings are of low-grade oedema to the SIJs and the corners of the vertebral bodies (the entheses).
Information for the radiologist • Presenting symptoms including sites of pain/tenderness. • HLA-B27 status if available (95% of patients are carriers). • Any history or clinical signs indicating UC, aortic valve disease, iritis, or pulmonary fibrosis.
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(a)
(b) Fig. 19.4 A 40-year-old male with stiffness in the back. a) Lateral lumbar spine radiograph showing smooth fusion of all the lumbar vertebral bodies. b) T1-weighted sacral MRI showing complete ankylosis of the SIJs consistent with ankylosing spondylitis.
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Degenerative disc disease Degenerative disc disease is mechanical degeneration of the intervertebral discs of the spine. This can lead to a prolapsed or herniated disc. About 90% of all disc prolapses occur at the L4/L5 and L5/S1 levels although the cervical spine can also be affected.
Clinical presentation • Non-specific back pain. • May present with radiation to the side of the disc prolapse if there is nerve root compression. • Motor symptoms develop as the disc compresses the nerve further. • Cauda equine syndrome is a combination of saddle (perineal anaesthesia), para-paresis, loss of bowel and bladder control due to a central disc prolapse compressing the cauda equine.
Imaging Plain film • Plain radiographs are often the first modality used, although they are of limited value. • They may show a reduction in disc height and degenerative changes affecting the facet joints. CT • CT is only used where MRI is contraindicated such as patients with aneurysm clips or severe claustrophobics. • CT may show a disc prolapse on careful review but it is of more value showing degenerative facet joints. • Definitive diagnosis can be made by instilling contrast into the CSF—known as a CT myelogram. This defines the prolapsed disc. MRI • MRI is the modality of choice for imaging of suspected disc prolapse. • The prolapsed disc can be visualized and any compression of the nerve can be seen. • Standard sets of images include sagittal and axial T1 and T2 sequences. • The nomenclature for disc prolapse has been standardized (Table 19.1).
Information for the radiologist • • • •
The dermatome, myotomes, and side of affected areas. Any associated neurology. Any signs of cauda equine syndrome. History of previous trauma, surgery to the spine or malignancy.
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Table 19.1 Nomenclature defined by North American Spine Society in 2001 Name
Meaning
Disc herniation
Localized displacement of disc material beyond the intervertebral disc space
Bulge
Disc between 50–100% circumferentially beyond the edges—not a form of herniation
Broad-based disc
Disc displaced between 25–50%circumferentially beyond the edges
Focal
Disc displaced 24 hours then the chance of any reasonable recovery decreases dramatically. However, there is no reason to scan someone in the middle of the night unless a surgeon is available who can operate immediately. It is much more appropriate to get the scan done first thing in the morning in time for the day-time emergency lists. Plain film These are helpful in showing areas of vertebral collapse or fracture but they cannot show what is causing the cord compression. MRI (Fig. 19.6) Other imaging modalities may provide useful information about trauma and vertebral collapse but MRI is the investigation of choice. This demonstrates what is causing the compression and over how much of a distance. Cord signal change is helpful and in trauma the presence of blood within the cord is a bad prognostic sign. In addition this will provide detail about other abnormalities in the region and give the surgeon a road-map for any planned surgery. CT myelography In patients who have contraindications for MRI then this is an alternative. Iodine dye is introduced into the dural sac using fluoroscopic control. CT is then used to look for indirect evidence of obstruction i.e. is there a level where the dye cannot pass through.
Information for the radiologist • Does the patient have any known malignancy? • Has the patient had any recent surgery—the risk of spinal infection is much higher where there has been recent thoracic or abdominal surgery? • Is the patient on any form of anticoagulation?
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CORD COMPRESSION
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Fig. 19.6 A 66-year-old male with sudden urinary incontinence. This shows collapse of the L3 vertebral body secondary to tumour replacement of the body. This is impinging upon the cauda equina and leading to severe nerve compression.
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Osteomyelitis Osteomyelitis is a debilitating condition with a considerable morbidity. It affects both children and adults, albeit differently. In children, the commonest route is by haematogenous spread. Infection typically localizes to the metaphysis with the lower limbs usually affected. The most common organism is Staphylococcus aureus. Chronic infection can lead to a Brodie’s abscess. In adults the commonest causes are direct inoculation or pre-existing conditions such as diabetes. Staphylococcus aureus and streptococci are the most commonly isolated organisms. Joint involvement is common. Chronic osteomyelitis in adulthood is usually due to a foreign body, chronic underlying disease, or previous trauma.
Clinical presentation • Fever, malaise, lethargy, and weight loss. • In children, there may be a history of recent infection. • In adults, there may be a previous history of surgery or IV drug abuse.
Imaging Plain film • Plain films can be insensitive in the early phase (there has to be 50% loss of bone before there is an appreciable radiographic change). • Ill defined lucency at the site of infection. In children this is usually at the metaphysis of the bone. • Periosteal elevation is seen later. • Chronic osteomyelitis is often characterized by necrotic bone termed a ‘sequestrum’. Bone scintigraphy • Osteomyelitis causes increased osteoblastic activity, which shows up as an area of increased uptake. • Scintigraphy can therefore be used to confirm areas of active infection and identify if there are multiple foci. CT CT is useful in identifying periosteal elevation, sequestra, or foreign bodies. MRI (Fig. 19.7) • MRI is the modality of choice for further investigation of osteomyelitis. • It can identify early oedema, periosteal reaction, soft tissue collections, and sequestra at the site of infection.
Information for the radiologist • Area of concern. • Past history of immunosuppression, chronic disease, IV drug abuse, surgery, and trauma. • Inflammatory markers.
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OSTEOMYELITIS
(a)
279
(b)
Fig. 19.7 A 20-year-old patient admitted with red and grossly swollen hindfoot. Figures 19.7a and 19.7b are T1-weighted gadolinium axial images of the hindfoot showing osteomyelitis of the calcaneus (arrowheads) and soft tissue pus (arrow).
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Discitis Discitis is infection of the intervertebral discs. It accounts for 2–4% of all skeletal infection with a male:female ratio of 3:1. There are 2 distinct affected age groups: children and adults aged >50. The infection may be confined to a single disc space or multiple levels with the lumbar spine commonly affected. The most commonly isolated pathogen is Staphylococcus aureus (60%) although other organisms including TB should always be considered. The three main routes of infection are: haematogenous (commonest), direct inoculation (iatrogenic), or contiguous spread. Discitis may progress to give vertebral body osteomyelitis.
Clinical presentation • • • •
Red flag signs (see Box 19.1) for spinal pathology. Acute, non-traumatic localized pain. Non-specific symptoms including fever, weight loss, and malaise. Chronic illnesses such as diabetes and immunosuppression predispose to it.
Box 19.1 Red flag signs for spinal pathology • • • • • • • •
Age of onset 50 years Thoracic pain Fever and unexplained with loss Bladder and bowel dysfunction History of carcinoma Ill health or previous medical illness Progressive neurological deficit Disturbed gait or saddle anaesthesia.
Imaging Plain film • This is relatively insensitive for early infection. • Loss of disc space. • Indistinct end plates. • Chronic changes include end-plate sclerosis or collapse. • Gradual disc obliteration and vertebral fusion. CT • CT is not routinely used in the initial work-up. • It has a role in assessment of the bony anatomy, to guide biopsies, and where the patient cannot tolerate an MRI. MRI • MRI is the initial modality of choice. • Standard sequences include T1-weighted, STIR and T1-weighted post-contrast sagittal and axial planes (Fig. 19.8). • T1 images will show low signal intensity changes to the disc and vertebral body with loss of disc height. • STIR images show high signal in the disc, adjacent vertebral end plates, and paravertebral soft tissues.
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DISCITIS
281
• Post-contrast T1 images show ring enhancement of pus and can be used to differentiate pus from oedema.
Information for the radiologist • Predisposing factors such as recent surgery? • What are the inflammatory markers? • Is there any evidence of sepsis?
(a)
(b)
Fig. 19.8 A 56-year-old patient with severe low back pain 1 month after an aortic aneurysm repair. a) Sagittal STIR image demonstrating oedema to the L4/L5 intervertebral disc, oedema to both the L4 and L5 vertebral bodies and an epidural abscess at this level. b) T1 gadolinium image showing peripheral enhancement of the abscess.
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Musculoskeletal conditions
Psoas abscess The psoas is a retroperitoneal muscle that originates from the lateral borders of T12 to L5. It lies in close proximity to the sigmoid colon, appendix, ureters, iliac lymph nodes, and the spine. Psoas abscesses are a result of its rich vascular supply and by conditions affecting the adjacent structures (Table 19.2). Primary psoas abscesses are commonly seen in children whilst secondary are seen in adults, commonly in IV drug abusers.
Clinical presentation • Non-specific abdominal pain/back pain. • Pyrexia, malaise, and weight loss. • Referred pain to the hips and femoral flexion.
Imaging Plain film This will not demonstrate a psoas abscess but it may point to the cause. Ultrasound UItrasound can be used to identify a psoas abscess although it may not be able to demonstrate the underlying cause. CT • Post contrast-enhanced CT is the modality of choice as it can identify both a psoas abscess (a ring enhancing area) and its underlying cause. • Both CT and ultrasound can be used to drain psoas abscesses percutaneously. MRI (Fig. 19.9) • MRI’s good soft tissue resolution will demonstrate these well. • MRI is superior to CT where there is an underlying spinal cause as it will clearly show spinal and epidural extension.
Information for the radiologist • Clinical presentation. • Inflammatory markers. • Any previous chronic diseases such as diverticulosis or history of IV drug abuse. Table 19.2 Predisposing causes for psoas abscess Disease site
Conditions
GI tract
Diverticulitis, appendicitis, Crohns, colorectal cancer, appendiceal tumour
GU tract
UTI, extracorporeal shock wave lithotripsy, GU cancers
Musculoskeletal infections
Vertebral osteomyelitis, discitis, infectious sacro-ilitis, septic arthritis
Others
Endocarditis, femoral artery catheterization, endocarditis, infected abdominal aortic aneurysm, spinal surgery
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Fig. 19.9 Coronal T1 gadolinium image of the retroperitoneum demonstrating bilateral psoas abscesses.
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Septic arthritis This is one of the true orthopaedic emergencies where the joint requires washout on the same day. The reason for this is that active intra-articular infection very quickly results in cartilage lysis. This will then lead to premature OA and even ankylosis later on. This means that any imaging should be performed in a timely manner.
Clinical presentation Patients with septic arthritis usually present with a swollen painful joint that they refuse to move. They will have raised inflammatory markers and may well have positive blood cultures. In very severe cases they may be systemically unwell.
Imaging Plain film All patients will have these. Bony changes such as lysis tend to not be visible until late on. In some joints (elbow and ankle) a joint effusion will be visible.
Further imaging Before any further imaging is undertaken the patient should be reassessed. If the diagnosis based upon the clinical and radiographic findings is definitely of a septic arthritis then the patient should go straight to theatre for a washout that will both confirm the diagnosis and treat the patient. Ultrasound This can be used to confirm the presence of an effusion and where appropriate be used to guide joint aspiration. MRI (Fig. 19.10) This is reserved for difficult cases where the diagnosis remains in doubt or where there is concern for widespread infection and collections.
Information for the radiologist • The patient’s inflammatory markers, immune status, and clotting status. • In addition, have they any predisposing clinical condition? • Finally what is the orthopaedic plan? No intervention should be performed by radiology without appropriate senior discussion with the on-call orthopaedic team.
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SEPTIC ARTHRITIS
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(a)
(b) Fig. 19.10 A 9-month-old child with swollen and painful right arm. a) T1 gadolinium axial image at the level of the shoulder joint. The arrow points to pus within the joint consistent with septic arthritis. b) Axial gadolinium image at the level of the mid arm showing further pus within the soft tissues.
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Swollen diabetic foot This is a relatively common and potentially very difficult clinical scenario to deal with. The 3 main areas of concern are: • Infection. • Trauma. • Charcot arthropathy. The problem is that with severe diabetes the patient may well have an insensate foot that renders clinical examination of little use. Therefore it is essential to take a very careful history and to not be misled by the lack of painful response.
Clinical presentation All of these conditions will present with a red, swollen foot. The key to differentiating these is the combination of the history, laboratory, and radiological tests. It is also very important to be aware that relatively trivial trauma can cause devastating injuries in the insensate diabetic foot.
Imaging Plain film (Fig. 19.11) • These remain the key frontline investigation. In trauma they will demonstrate any injury as well as act as a baseline for follow-up. • Charcot feet show evidence of advanced OA with destruction, disorganization, debris, dislocation, distention, and increased density. In an acute Charcot foot there will be swelling, bone resorption, and effusions. • In infection there will be osteolysis, soft tissue swelling, and periosteal reactions. CT This is useful for demonstration of the bony anatomy, particularly where there is suspicion for a fracture. MRI This is used for assessment of infection and the acute Charcot foot. Both will show similar changes with inflammation, effusions, and bone oedema. However on post-contrast sequences there may well be soft tissue or intra-osseous abscesses in infection. Where there are no collections the MRI findings should be taken in conjunction with laboratory tests to distinguish between these 2 clinical conditions.
Information for the radiologist Inflammatory markers.
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SWOLLEN DIABETIC FOOT
287
(a)
(b) Fig. 19.11 A 55-year-old diabetic presented with a painless, swollen foot after tripping over his dog. a) A dorsiplantar radiograph showing marked abnormality to the midfoot. The lateral (b) shows that this is in fact a dislocation across the midfoot (arrowhead). The vascular calcification (arrow) is a classical finding in diabetics.
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Musculoskeletal conditions
Loose (painful) joint replacement The vast majority of joint replacements last for many years, without any problems. In a small percentage they loosen either secondary to infection or loosening of the prosthesis within the cement mantle.
Clinical presentation Patients presenting with a painful joint after a prosthesis can be divided into 2 groups. • Early presentation: within 18 months. These can be considered to be infected until proven otherwise. • Late presentation: after 18 months. These can either be loosening or infection. The longer the prosthesis has been in situ the less likely infection is likely to be the cause.
Imaging Plain film (Fig. 19.12) All patients get radiographs as part of their follow-up. Both infection and loosening show up as lysis of the cement at the bone–cement interface. Infection tends to cause rapid changes whereas those of aseptic loosening are more gradual. Ultrasound This can be used to demonstrate joint effusions and collections. In addition it can used to guide needle aspiration where indicated. CT/MRI Both CT and MRI can be used to gain further information regarding the bony and soft tissue anatomy. Unfortunately the metalwork can significantly degrade the image quality and therefore these are limited to specific cases. Fluoroscopy Surgeons will usually require confirmation of infection prior to intervening. Fluoroscopy is a good technique to obtain a sample as not only can it be used to guide in the needle but also the images captured are solid evidence of where the sample was obtained.
Information for the radiologist • When was the prosthesis put in? • What are the patient’s inflammatory markers? • What is the operative plan?
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LOOSE (PAINFUL) JOINT REPLACEMENT
289
Fig. 19.12 AP radiograph of right hip replacement showing patchy cement lysis of the right femoral component consistent with infection.
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Musculoskeletal conditions
Primary bone tumours Malignant primary bone tumours are a varied group of neoplasms. They account for only 2/1000 cancers diagnosed and are predominantly seen in children or adults >55 years. They arise from the various elements of bone: osteoid (osteosarcoma), cartilage (chondrosarcoma), and neural elements (Ewing’s sarcoma).
Clinical presentation • • • • • •
The age of presentation is the key to the differential diagnosis. Pain is the commonest presentation. Weight loss or malaise. Fever of unknown origin. Swelling at the site of pain. Pathological fractures.
Imaging Plain film (Fig. 19.13) • This is the initial imaging modality of choice. • 2 films are taken in perpendicular planes. • 1 of these views needs to show the whole length of the bone. • The following features are important: • Single or multiple. • The site of the lesion (epiphyseal, metaphyseal, or diaphyseal). • The margins of the lesion (well defined or ill defined). • Bony expansion and breach of cortex. • Presence of calcification in the lesion or surrounding the lesion. • Periosteal reaction. • A chest radiograph is indicated to exclude metastases. CT • This is usually only used to stage the chest. • Where necessary CT can be used to assess calcification of the lesion. MRI • This is used for local staging to assess the full extent of the lesion, which compartments it has breached and whether local neurovascular bundles are involved. • Standard protocols include T1, fat saturated T2 sequences, and post-contrast T1 images in orthogonal planes. Scintigraphy A bone scan is indicated to look for bony metastases.
Information for the radiologist • Age and presenting symptoms. • History of malignancy. • Biochemical markers including parathormone levels if suspicion of hyperparathyroidism or renal failure. • Tumour markers.
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PRIMARY BONE TUMOURS
(a)
291
(b)
Fig. 19.13 A 67-year-old male presented with knee pain. a) AP and b) lateral radiographs of the proximal tibia show an area of ill-defined sclerosis with periosteal reaction. This proved to be late onset osteosarcoma of the tibia.
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Bone metastases Bony metastases are common. They may be either osteolytic (bone destroying) or osteosclerotic (bone forming). Primary malignancies produce different types of metastases (see Table 19.3) with osteolytic ones the most common. Table 19.3 Common malignancies and type of bone metastases Name
Meaning
Lung
Usually osteolytic
Breast
Either osteolytic or osteosclerotic
Colorectal
Osteolytic
Prostate
Osteosclerotic
Renal cell carcinoma
Osteolytic with expansion
Upper GI cancers
Osteolytic
Gynaecological
Usually osteolytic
Clinical presentation • Non-specific pain. • Pyrexia. • Fractures of the involved bones.
Imaging Plain film (Fig. 19.14) • Radiography is the usual first-line investigation. • Multiple myeloma should always be considered in the differential diagnosis. • Lytic bone lesions may only cause a subtle discontinuity of the trabeculae. Lung is the most common primary. • Sclerotic metastases show up as either a generalized bone density increase or as discrete deposits. In men the commonest primary is prostate and in women it is breast. • Long-bone fractures with irregular and patchy bone texture should raise the suspicion of a metastasis. • Femoral deposits need prompt recognition, as they can be prophylactically fixed with an intramedullary nail. CT • CT is has a high sensitivity for metastatic deposits. • CT shows metastases best bone windows. • Definitive diagnosis can be made by a CT-guided biopsy. Bone scan • Bone scintigraphy is very good at demonstrating the full extent of bony metastatic spread.
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• It shows areas of high bone turnover. Therefore sclerotic metastases may be poorly demonstrated. MRI MRI is reserved for problem solving, e.g. differentiating between vertebral body collapse secondary to osteoporosis or metastasis. PET-CT • PET is both a functional and anatomical imaging method that can identify metastatic deposits by their glucose uptake. • PET has a high sensitivity and specificity for identifying bony metastasis and is used after discussion at the MDT.
Information for the radiologist • Area of the pain. • Oncological history. • Tumour markers and calcium levels.
(a)
(b)
Fig. 19.14 A 70-year-old patient presented unable to weight bear after a minor fall. a) AP and b) lateral radiographs show an ill-defined lytic/sclerotic lesion in the intertrochanteric region with a break in the superior cortex. The appearances are consistent with a pathological fracture through a metastasis.
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Myeloma Myeloma is a malignancy characterized by monoclonal proliferation of malignant plasma cells. It is the most common primary malignant neoplasm in adults and commonly occurs in the 5th–8th decades. • It occurs in 2 forms: • Disseminated (more common). • Solitary. • This represents the early stages of multiple myeloma and precedes the disease by 1–20 years. • Occurs most commonly in the thoracolumbar spine >pelvis >ribs >sternum.
Clinical presentation Bone destruction This can lead to: • Vertebral collapse. • Hypercalcaemia. Bone marrow infiltration • Anaemia. • Neutropenia. • Thrombocytopenia. • Renal impairment.
Imaging Plain film Due to the multicentricity of the disease process, a skeletal survey is required to ensure that no regions of disease have been missed. • Diffuse permeative lesion (can mimic sarcoma or lymphoma). • Widespread osteolytic lesions with a punched-out appearance and endosteal scalloping. • Expansile osteolytic lesions (ballooning) in ribs, pelvis, long bones. • A soft tissue mass may be identified adjacent to the area of bone destruction. Bone scintigraphy Myeloma is one of the lesions that is not characteristically ‘hot’ on a bone scan, therefore plain films are commonly used for the skeletal survey. CT (Fig. 19.15) • Acute myeloma: Swiss-cheese pattern, with multiple ‘holes’ in the bone. • Chronic myeloma: dense, thick, bony struts. MRI MR imaging allows characterization of the bone lesions and any associated soft tissue components. • T1-weighted: multiple focal hypointense area. • T2-weighted: corresponding hyperintense regions. • Characteristic ‘mini-brain’ appearance.
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MYELOMA
295
Information for the radiologist • Plasma electrophoresis/biochemistry results. • Site of patient’s symptoms. • History of previous solitary plasmacytoma.
Fig. 19.15 Sagittal CT reformat of the cervical spine demonstrating lytic lesions in the posterior elements of C6 and the body of T1 (arrows) consistent with multiple myeloma.
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Musculoskeletal conditions
Benign bone lesions The most common metaphyseal and epiphyseal benign bone lesions are simple bone cysts, giant cell tumours, and aneurysmal bone cysts.
Clinical presentation • Asymptomatic. • History of minor trauma that is unrelated to the condition. • May present with a pathological fracture.
Imaging Plain film (Fig. 19.16) Simple bone cyst • Skeletally immature patients (epiphyseal fusion has not yet taken place). • This is the diagnostic modality of choice. • Simple bone cysts are usually well circumscribed with a single cyst and expansion of the bone. They are commonly seen in the humeral head. • Pathological fractures through them are common with the ‘fallen fragment’ sign, a fragment of bone seen within the cyst that has fractured. Aneurysmal bone cyst (ABC) • Skeletally immature patients (epiphyseal fusion has not yet taken place). • An expanded lesion in the bone with multiple cystic areas. • ABCs do not extend to the joint surface. • Pathological fractures occur but they do not show the fallen fragment sign. Giant cell tumour (GCT) • GCTs are seen in skeletally mature patients. • This tumour is a multicystic expansile lucent lesion. • GCTs extend to the joint surface. CT CT is used to characterize the fractures in the tumours. MRI MRI is used to demonstrate the full extent of these lesions as well as the characteristics of their contents.
Information for the radiologist • Clinical presentation. • Patient’s age. • Inflammatory markers.
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BENIGN BONE LESIONS
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(a)
(b) Fig. 19.16 a) AP and b) axial shoulder radiographs taken after patient complained of pain in their shoulder after a fall. These demonstrate a well-defined lucent lesion in the proximal humerus. There is a clear zone of transition. There is a break in the lateral cortex. The appearances are typical of a fracture through a unicameral bone cyst.
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Diaphyseal benign bone tumours Benign bone lesions are relatively uncommon. There are only 3 benign bone lesions that occur in the diaphysis: the fibrous cortical defect (of no clinical concern), fibrous dysplasia (seen in children and resulting in mild deformity of bone), and osteoid osteoma (painful condition affecting children).
Clinical presentation • Fibrous cortical defects and fibrous dysplasia are usually asymptomatic. • Non-specific pain. In the case of osteoid osteoma, children get night pain relieved by NSAIDs. • Fractures of the involved bones.
Imaging Plain film (Fig. 19.17a) • Plain radiographs are the modality of choice. • A fibrous cortical defect is a lytic lesion adjacent to the cortex that disappears after fusion of the growth plate. • Fibrous dysplasia is a lytic bone lesion with well-defined margins and a ‘ground glass’ matrix. • Osteoid osteoma is a bone-forming tumour that presents as a thickened area of cortex in a long bone although vertebral body osteomas are also known. CT • CT has a high sensitivity for osteoid osteoma and is the modality of choice to confirm the diagnosis. • CT shows a thick cortex with a lucent area in the centre. • Definitive diagnosis is often made by a CT-guided biopsy and is used to guide therapy. Bone scintigraphy Osteoid osteomas have high bone turnover and will show as a focus of high uptake. MRI (Fig. 19.17b) MRI is reserved for difficult atypical cases.
Information for the radiologist • Area of the pain. • Relevant history. • Relevant biochemical results including tumour markers and calcium levels.
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DIAPHYSEAL BENIGN BONE TUMOURS
(a)
299
(b)
Fig. 19.17 An 8-year-old patient presented with a 2-month history of left thigh pain. a) AP radiograph shows mid diaphyseal lesion with chronic perosteal reaction and medullary lysis. b) T1FS coronal MRI shows extensive inflammation associated with this but no soft tissue mass. The appearances are consistent with eosinophic granuloma.
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Sclerotic bone lesions The underlying cause for these range from congenital abnormalities through to malignant secondaries.
Benign causes • • • • • • •
Osteoid osteoma. Bone island. Chondroid lesion. Paget’s disease. Infection. Sequestrum. Bone infarct.
Clinical presentation This is important as presentation can help to differentiate the underlying cause. Incidental finding In an otherwise well patient this is an essentially reassuring scenario and would imply that may it well be long-standing in nature. This does not exclude aggressive lesions. Raised inflammatory markers In this setting an inflammatory process, most likely infection, should be actively investigated as obviously if this is the cause then it is treatable. Pain The type of pain can be very helpful as ostoid osteomas classically present with night pain that is relieved by NSAIDs. Night pain is, as a rule, a worrying symptom and will warrant a full work-up for an aggressive aetiology.
Imaging Plain film These remain the mainstay for initial investigation and usually will provide the diagnosis. Key findings are the transition zone, the age of the patient, and the location of the lesion. Lesions with ill-defined margins tend to be aggressive whereas a well-demarcated margin with a sclerotic edge is reassuring. CT (Fig. 19.18) This is good for looking at the bony anatomy and the zone of transition. CT will confirm the diagnosis of osteoid osteoma by confirming its intracortical location. In cases of infection it will demonstrate sequestra (dead pieces of bone) that can act as nutrient reservoirs for bugs. MRI This is good for demonstrating the soft tissue elements of a lesion as well as involvement of joints and local neurovascular bundles. In cases of infection this will show the full extent of any osteomyelitis as well as any abscesses.
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SCLEROTIC BONE LESIONS
301
Information for the radiologist • Does the patient have a known primary tumour? • Is the lesion painful and if so when.
Fig. 19.18 Coronal CT reformation of the pelvis and lumbar spine showing widespread sclerotic lesions consistent with disseminated prostate metastases.
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Paget’s disease This is a condition where there is a localized increase in size and numbers of osteoclasts leading to an increased rate of osteolysis. This is followed by a compensatory increase in osteoblasts causing accelerated bone deposition. This combination of factors results in the classical Pagetic appearance with a larger, chaotic and sclerotic bone. In early stages areas of ostolysis will be seen, classically in the skull—osteoporosis circumscripta.
Clinical presentation • This rarely occurs in patients 1. • Osteopenia: T −2.5. • Osteoporosis: T 6mm. Lateral This should include the calcaneus and the base of 5th metatarsal. CT This is used if there is a strong clinical suspicion of a fracture, but the plain films are negative, or if detailed reconstructions are required for surgical planning. MRI This is indicated for significant ligamentous, cartilage, osteochondral, and soft tissue injuries.
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ANKLE TRAUMA
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Classification The Weber–AO classification system is the most commonly used ankle fracture classification system. This refers to injuries to the lateral malleolus: • Type A: fracture below the ankle joint. • Type B: fracture at the level of the joint. • Type C: fracture above joint level, which tears the syndesmotic ligaments.
(a)
(b)
Fig. 20.13 A 25-year-old fell awkwardly whilst playing football. a) AP and b) lateral radiographs demonstrate a multisegmental fracture of the distal fibula above the level of the tibiofibular syndesmosis. The arrow points to a widened medial joint space. This is therefore likely to be unstable.
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Trauma
Calcaneal fractures The calcaneus or heel bone is the largest of the tarsal bones. It supports the total body weight thereby facilitating walking. The subtalar joint (the articulation between the talus and the calcaneus) facilitates inversion and eversion.
Clinical presentation This is the most commonly injured bone of the hind foot. Fractures are either following a fall from a height or stress fractures in the elderly. Fractures can be intra-articular (75%) or extra-articular (25%). The most important distinction is whether the subtalar joint is involved, due to its impact on walking.
Imaging Plain film These are the initial investigation of choice. Lateral (Fig. 20.14a) This view can be carried out for either a specific calcaneal injury or as part of the investigation for an ankle injury. Therefore it is important to always look for a calcaneal fracture when assessing ankle radiographs. It is important to assess Boehler’s angle (normal range 20–40°) on the lateral view as this may be the only indication of an injury. Axial This is a specific view of the calcaneus. CT (Fig. 20.14b) This is used to provide detailed reconstructions of the full extent of the injury. The surgeons will particularly want to know the extent of damage to the subtalar joint. MRI This is only rarely used if there is concern for major soft tissue injuries.
Information for the radiologist The mechanism as injuries to the hind foot, after a fall from a height, should raise concern for spinal injuries.
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CALCANEAL FRACTURES
(a)
339
(b)
Fig. 20.14 A 20-year-old male who jumped from a second floor window and was unable to weight bear after. a) Lateral ankle radiograph showing significant fragmentation of the calcaneus. b) Axial CT image fully demonstrating the true extent of the injury.
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Chapter 21
Gastrointestinal differential diagnosis Abdominal calcification 342 Ascites 342 Colonic dilatation 342 Pneumoperitoneum 343 Pneumatosis intestinalis (gas in the bowel wall) 343 Small bowel dilatation 343 Strictures 344
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Gastrointestinal differential diagnosis
Abdominal calcification Calcification seen on an abdominal radiograph may be due to calcification of normal structures, or calcification indicating pathology.
Calcification of normal structures • • • •
Ribs (costal cartilage). Mesenteric nodes. Pelvic veins (phleboliths). Prostate.
Abnormal structures to contain calcium i.e. calcium indicates pathology: • Pancreas. • Renal parenchyma. • Blood vessels and aneurysms. • Gall bladder (e.g. porcelain gallbladder). • Uterus (fibroids).
Calcium is pathological • • • • •
Biliary calculi. Renal calculi. Appendicolith. Bladder calculi. Teratoma.
Ascites • • • • • •
Cirrhosis. Tumours. Hypoalbuminaemia. Peritonitis. Increased pressure in vascular system distal to liver. Lymphatic obstruction.
Colonic dilatation Non-toxic (without abnormal mucosa) • Mechanical obstruction (e.g. carcinoma). • Ileus: paralytic/secondary to electrolyte imbalance. • Pseudo-obstruction: signs or symptoms of LBO but no organic lesion as cause. • Purgative abuse.
Toxic (with mucosal abnormalities) • Inflammatory: • UC. • Crohn’s disease. • Pseudomembranous colitis. • Ischaemic colitis. • Infective (e.g. dysentery).
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SMALL BOWEL DILATATION
343
Pneumoperitoneum • Perforation of a gas containing viscus: • Peptic ulcer. • Secondary to inflammation, e.g. diverticulitis, toxic megacolon, necrotizing enterocolitis, appendicitis. • Infarction. • Malignant neoplasm. • Obstruction. • Iatrogenic. e.g. postoperative, dialysis, etc. (may take a couple of weeks to resorb, but should reduce in amount over time). • Pneumomediastinum. • Pneumothorax (pleuroperitoneal fistula). • Per vaginum. • Idiopathic.
Pneumatosis intestinalis (gas in the bowel wall) • Primary (15%): • Pneumatosis coli. • Secondary: • Immunosuppressive and steroid therapy. • Leukaemia. • Colitis and enteritis of any cause (UC, Crohn’s, ischaemia, severe infective colitis). • Collagen disorders (scleroderma).
Small bowel dilatation • • • • • •
Mechanical obstruction. Paralytic ileus. Ischaemia. Crohn’s disease. Radiotherapy. Lymphoma.
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Strictures Oesophageal Strictures of the oesophagus can be separated into smooth and irregular, as they appear at contrast swallow studies. Smooth • Inflammatory: • Peptic. • Scleroderma. • Corrosives. • Iatrogenic, e.g. after chronic NG tube. • Neoplastic: • Carcinoma (occasionally squamous carcinoma). • Mediastinal tumours. • Leiomyoma. • Achalasia. Irregular • Neoplastic: • Carcinoma. • Leiomyosarcoma. • Carcinosarcoma. • Lymphoma. • Inflammatory: • Reflux (more commonly smooth). • Crohn’s disease. • Iatrogenic: • Radiotherapy. • Fundoplication.
Small bowel • • • • •
Adhesions. Crohn’s disease. Ischaemia. Radiation. Tumours.
Large bowel • Neoplastic: • Carcinoma. • Lymphoma. • Inflammatory: • UC, Crohn’s, radiotherapy, diverticulosis. • Ischaemia: • Commonest site is splenic flexure at the vascular watershed area. • Infective: • e.g. TB. • Extrinsic masses: • Inflammatory, tumours, endometriosis.
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Gastrointestinal presenting syndromes Upper abdominal pain 346 Vomiting 348 Jaundice 350 Melaena 352 Iron deficiency anaemia 353 Diarrhoea 354 Abdominal distension 355 Weight loss 356
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Upper abdominal pain Differential diagnosis • • • • • • • • •
Gastritis. Stomach/duodenal ulceration. Cholecystitis/cholangitis. Pancreatitis. Subphrenic abscess. Viscus perforation. Stomach cancer. Liver cancer. Pancreatic cancer.
Imaging The differential diagnosis of upper abdominal pain is wide and the choice of appropriate investigation is guided by obtaining a good clinical history and examination to identify typical features associated with certain conditions. Investigations utilized in upper abdominal pain include plain radiography, abdominal ultrasound, OGD, and CT. OGD is not an imaging modality and is best suited to investigation of possible gastritis and peptic ulcer disease. Plain radiographs (erect chest radiograph and abdominal radiograph) may be helpful as the initial investigation to assess for intestinal obstruction or viscus perforation. They can also provide additional information on the presence of gallstones or renal calculi. TA ultrasonography is the investigation of choice in hepatobiliary or gallstone disease. It also provides information on other important structures within the abdomen which are interrogated during the scan such as the kidneys, spleen, and aorta. CT is being used increasingly for definitive assessment of the abdomen either as a primary modality, usually when the patient is acutely unwell or as a problem-solving tool when initial investigations have either identified an abnormality which requires further evaluation or when the patient’s ailment remains unexplained. Owing to its optimal depiction of the solid intra-abdominal viscera, small and large bowel, and vascular tree its main roles are in diagnosing acute pathology in addition to staging and follow-up of chronic illness and malignancy.
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Vomiting Vomiting is a common and non-specific symptom. A myriad of causes can trigger the vomiting centre in the brain, many of which will not require imaging. A careful history of the duration and type of symptoms along with the patient’s age and associated symptoms will guide the differential and inform whether imaging is required.
Causes • GI: gastroenteritis, gastric outlet obstruction, bowel obstruction, ileus, gastroparesis. • Inflammatory: e.g. appendicitis, acute cholecystitis, pancreatitis. • CNS: head injury, raised intracranial pressure, meningitis, labyrinthine neuronitis, migraine. • Metabolic/endocrine: hypercalcaemia, uraemia, hyponatraemia, diabetic ketoacidosis. • Drugs: chemotherapy, antibiotics, opiates, digoxin. • Alcohol. • Other: pregnancy, MI, UTI, psychogenic.
Clinical presentation History • Distinguish true vomiting from regurgitation. • Duration of symptoms: acute, chronic, or recurrent. • Timing: relation to meals, early morning (pregnancy, raised intracranial pressure). • Content of vomitus: bile, blood, coffee grounds, faeces. • Abdominal pain, fever, diarrhoea. • Constipation. • Headache, neck stiffness, focal neurology, vertigo. • Pregnancy symptoms, e.g. amenorrhea. • Weight loss. • Previous abdominal surgery: consider obstruction secondary to adhesions. • Primary malignancy: obstruction or cerebral metastases. Clinical examination The most relevant findings to inform imaging are signs of obstruction (high pitched bowel sounds, peritonism or abdominal mass and signs of raised intracranial pressure or focal neurology to indicate a CT head.
Imaging The type of imaging will be guided by the differential diagnosis and the patient’s age. Imaging is not indicated in many causes of vomiting, e.g. gastroenteritis or pregnancy. The main role of imaging is to diagnose or exclude mechanical obstruction or intracranial pathology. Imaging may also play a role in diagnosing inflammatory conditions such as appendicitis. Plain film An abdominal radiograph is the first-line investigation in suspected bowel obstruction. Features include dilated bowel proximal to an obstruction with a paucity of gas distally. Look for free gas in associated perforation.
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VOMITING
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Ultrasound May be first-line investigation of neonates or infants with vomiting, e.g. ?pyloric stenosis or adults with features of inflammatory causes, e.g. pancreatitis or cholecystitis. CT CT head is the investigation of choice in suspected neurogenic vomiting, e.g. post-head injury or in a patient with features of raised intracranial pressure or a known primary malignancy at risk of cerebral metastases. CT of the abdomen and pelvis is carried out in bowel obstruction to look for the site and cause of obstruction. Other inflammatory causes of vomiting such as appendicitis, pancreatitis, and cholecystitis may be detected. Fluoroscopy Upper GI contrast studies are used in suspected gastric outlet obstruction and in children. Nuclear medicine Radionuclide gastric emptying study may be used in investigation of unexplained nausea and vomiting.
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Gastrointestinal presenting syndromes
Jaundice Jaundice is clinically detectable when the serum bilirubin concentration is in excess of 50μmol/L (with a normal value of 95% malignant tumours stomach, other tumours include lymphoma and GIST. • Risk factors: Helicobacter pylori, atrophic gastritis, smoking, pernicious anaemia, blood group A, adenomatous polyps, diet. • 5-year survival rates remain low at about 15%.
Clinical presentation Often non-specific and late. New-onset dyspepsia, dysphagia, vomiting, anorexia, weight loss, or haematemesis warrant investigation. Patients with advanced disease often have constitutional symptoms of anorexia and weight loss.
TNM staging • • • • • • • • • •
Tis: carcinoma in situ. T1: invading lamina propria/submucosa. T2: invading muscularis propria/subserosa. T3: penetrates subserosa. T4: invasion of adjacent structures. N1: metastasis to 1–6 regional nodes. N2: metastasis to 7–15 regional nodes. N3: metastasis to >15 regional nodes. M0: no distant spread. M1: distant metastasis.
Imaging OGD (and biopsy) is the investigation of choice for diagnosing gastric cancer. The role of imaging is in the accurate preoperative staging of the disease once a diagnosis has been established. Laparoscopy performed in patients considered for radical surgery, as may identify occult peritoneal metastasis. CT (Fig. 23.2) CT provides staging information on the tumour mass, loco-regional/ distant lymphadenopathy, and metastatic spread of disease. EUS In patients with no evidence of distant disease, EUS may be used to evaluate local extent of the tumour as it able to define the individual layers of the gastric wall and thus accurately assess the depth of invasion of the gastric tumour and local invasion. PET Role is still being evaluated; may have a role in recurrent disease and assessment of treatment response.
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GASTRIC CANCER
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Information for the radiologist Clinical history and duration of symptoms with emphasis on features consistent with malignancy are essential. Endoscopic evaluation and histological diagnosis is important before embarking upon staging investigations if the patient is a candidate for active treatment.
Fig. 23.2 Axial CT showing abnormal thickening of the stomach, with local lymphadenopathy (short arrows), and extension into the perigastric fat (long arrow). Low attenuation lesions within the liver are metastases.
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Colonic cancer • UK: 3rd commonest malignancy; 2nd commonest cancer death. Risk factors: chronic inflammatory bowel disease, hereditary polyposis and non-polyposis syndromes, previous bowel cancer, smoking. • Majority adenocarcinomas arise in pre-existing adenomatous polyps.
Clinical presentation • Most tumours arise in the left colon, causing rectal bleeding, altered bowel habit, and colicky pain. • Right-sided tumours present with iron deficiency anaemia/RIF mass.
TNM staging • • • • • • • • • •
Tis: carcinoma in situ. T1: invading submucosa. T2: invading muscularis propria. T3: invading through muscularis propria. T4: invasion of adjacent structures/perforates peritoneum. N0: no node spread. N1: metastasis in 1–3 regional nodes. N2: metastasis in ≥ 4 regional lymph nodes. M0: no distant spread. M1: distant metastasis.
Imaging Colonoscopy is the first-line test for tumour detection and biopsy. Imaging studies are less invasive, indicated in patients unable to undergo/ failed colonoscopy. CT colonography (CTC) has overtaken double contrast barium enema (DCBE) as the colorectal imaging method of choice, with better sensitivity, and specificity approaching colonoscopy. Plain film Useful in suspected acute bowel obstruction (presenting feature in small bowel >colon >pancreas >oesophagus. • Usually diffuse large B-cell (~50%)/marginal zone/MALT (~40%). • Risk factors: coeliac disease, immunoproliferative small-intestinal disease (alpha-chain disease), chronic lymphatic lymphoma, previous extra-intestinal lymphoma.
Clinical presentation • General malaise and anorexia. • Symptoms of intestinal obstruction if the affected bowel lumen is compromised. • May give rise to intussusception. • Dysphagia if the oesophagus is affected.
Imaging For diagnosis, monitoring of response or complications of therapy. Plain film Chest radiograph may demonstrate lymphadenopathy. Fluoroscopy Barium swallow/meal/enema may show large irregular mural filling defects/ fine submucosal nodules/thickening of folds. Ultrasound • Can assess spleen/liver, but difficult to assess infiltrative disease. • Good for assessment of superficial nodal masses, and ultrasoundguided biopsies can be performed to gain tissue diagnosis. CT (Fig. 23.5) Most useful investigation. The extent of spread of the mass and evaluation of sites of neoplastic involvement can be demonstrated. PET May be used to identify active disease prior to, or post treatment.
Information for the radiologist • Clinical symptoms if primary presentation—therefore choice of most appropriate radiological investigation can be made. • Biopsy results. • Relevant past medical history, e.g. coeliac disease.
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GASTROINTESTINAL LYMPHOMA
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Fig. 23.5 Axial CT showing circumferential thickening of the caecum, in a patient with lymphoma. The bowel is thickened, with a dilated lumen, and there is no proximal obstruction.
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Liver tumours • Benign: haemangiomas are the commonest liver lesions, along with hepatic adenomas and focal nodular hyperplasia. • Malignant: hepatocellular cancer (HCC) is one of the world’s commonest cancers. It is associated with chronic liver disease, particularly hepatitis B and C. Metastases can occur in the liver commonly from colon, lung, breast, pancreas and stomach cancers.
Clinical presentation • • • •
Pain (as the liver capsule is stretched). Deranged LFTs or jaundice. Anorexia or weight loss. Many liver tumours are small and clinically undetected. In metastatic disease, symptoms may only be apparent from the primary tumour.
Imaging Ultrasound Good first-line test, used for follow-up of patients at risk of HCC. Used for image guided-biopsy. CT (Fig. 23.6) • Follow-up of patients with a known primary malignancy that is known to have spread to the liver. • Different timing of contrast enhancement may be used depending on the type of tumour. MRI Excellent tool for problem-solving of liver tumours if a lesion identified on ultrasound or CT requires further characterization.
Information for the radiologist • Relevant medical history, e.g. malignancy, cirrhosis, long-term use of the oral contraceptive pill (adenoma risk factor). • Haematology and biochemistry results: especially LFTs, and clotting if a biopsy is to be performed.
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LIVER TUMOURS
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Fig. 23.6 Axial CT showing multiple low attenuation lesions within the liver, in keeping with metastases.
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Cholangiocarcinoma • >95% adenocarcinoma, arise from biliary epithelium. • Risk factors: age (>60 years), chronic inflammation, e.g. primary sclerosing cholangitis, viral hepatitis, cirrhosis and liver fluke (parasitic) infestation only account for a few. • Classified as intrahepatic, hilar (Klatskin) or extrahepatic (most common).
Clinical presentation • • • •
Often progress insidiously and present late. Poor prognosis: 5-year survival rate gastric ulcers. Risk factors: Helicobacter pylori, drugs (aspirin, NSAIDs, steroids, bisphosphonate), smoking, stress.
Clinical presentation Gastric ulcers classically present with intermittent, burning epigastric pain occurring shortly after meals with minimal relief by food or antacids. Duodenal ulceration typically causes pain before meals and at night, relieved by bland foods and alkalis such as milk. However, there is much symptom overlap and often ulcer type differentiation cannot be made on history alone. ALARM symptoms: anaemia; loss weight; anorexia; recent onset; melaena/ haematemesis; swallowing difficulties.
Imaging OGD is the investigation of choice for diagnosing peptic ulcer disease. In addition to direct visualization, tissue biopsies can be taken to assess for H. pylori infection and malignancy. Therapeutic intervention for bleeding ulcers is also commonly performed. Plain film Pneumoperitoneum if perforation has occurred. CT (Fig. 23.12) Used for identification of complications, such as abscess formation, detection of free gas. Fluoroscopy Traditional test for ulceration was a barium study, but this has been superseded by endoscopy, which allows biopsy and direct visualization.
Information for the radiologist A clear, concise history outlining pertinent risk factors, i.e. relevant medications, concerning features such as anorexia or weight loss and supportive examination findings or biochemical derangement, i.e. microcytic anaemia is ideal. In the acute situation, if a viscus perforation is suspected, clinical history and examination findings, relevant blood tests, i.e. serum lactate and plain radiograph findings are essential.
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STOMACH/DUODENAL ULCERATION
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Fig. 23.12 Coronal CT showing thickening of the distal stomach (arrow) with surrounding inflammatory change, in a patient with a locally perforated peptic ulcer.
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Crohn’s disease Chronic recurrent inflammatory condition of the GI tract of unknown aetiology, characterized by transmural inflammation. Lesions may occur anywhere in the GI tract but are most common in the small bowel (especially the terminal ileum) and the colon. Discontinuous and asymmetric involvement is characteristic. The earliest pathological feature is apthoid ulceration which progresses to frank ulceration. Complications include fistula formation, abscesses, and strictures. It may also cause complications outside of the GI tract.
Clinical presentation Peak incidence 15–25 years. A 2nd peak has been reported in the 50–80-year age group. Onset may be insidious. Chronic diarrhoea which may be bloody, abdominal pain and weight loss are common presenting symptoms. Complications • Hepatobiliary: hepatic steatosis, gallstones, primary sclerosing cholangitis. • Pancreatitis. • Urinary tract: nephrolithiasis, enterovesical fistula. • Musculoskeletal: arthritis.
Imaging Imaging was traditionally by contrast studies (DCBE and SBFT), however these have been replaced by non-ionizing investigations magnetic resonance enterography (MRE) and ultrasound. Ultrasound Thickened, hyperaemic small bowel loops, most useful in imaging young thin patients. MRE (Fig. 23.13) Demonstrates disease distribution, activity, response to treatment, enteric and extra-enteric complications, e.g. perianal fistulae. CT Used in acute presentations to detect complications, disease extent and detection of extra-enteric complications.
Information for the radiologist Due to the nature of the disease, patients with Crohn’s disease are likely to undergo repeated examinations in the course of their treatment, and as a result investigations should only be performed when they will help guide management.
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CROHN’S DISEASE
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(a)
(b) Fig. 23.13 a) Axial and b) coronal images from a MRE study. There is a loop of abnormal pelvic small bowel showing wall thickening, mucosal enhancement and engorged vessels in keeping with active disease.
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Ulcerative colitis Relapsing and remitting continuous non-transmural inflammation of the rectum (proctitis ~50%) and colon (left-sided ~30%; pancolitis ~20%), may be associated ‘backwash ileitis’ (inflammation of the terminal ileum). Histological diagnosis from endoscopic biopsy.
Clinical presentation • Gradual onset diarrhoea. Abdominal pain is common. Systemic symptoms during attacks. • Extra-enteric signs seen at imaging: arthritis, sacro-iliitis, ankylosing spondylitis, fatty liver, PSC, cholangiocarcinoma, amyloidosis. • Complications: perforation, bleeding, toxic megacolon, venous thrombosis, colonic cancer (risk ~15% with pancolitis for 20 years).
Imaging Imaging used in diagnosis, monitoring therapy response or complications. Plain film (Fig. 23.14) Abdominal X-ray: acute setting only, looking for perforation, abnormal dilatation (toxic megacolon >6cm), thickening of bowel wall and thumbprinting (mucosal oedema). CT In acute setting may be used to confirm colitis and extent of disease. May help to differentiate causes of colitis. Demonstration of complications. MRI Used in some centres as an alternative to CT for imaging the colon. Useful in investigating specific complications, e.g. primary sclerosing cholangitis/ cholangiocarcinoma, sacro-iliitis. In pancolitis with an equivocal biopsy MRE can be used to help differentiate UC from Crohn’s disease. Fluoroscopy DCBE contraindicated in the acute setting due to risk of perforation!
Information for the radiologist • Clinical symptoms if primary presentation—therefore choice of most appropriate radiological investigation can be made. Information on any biopsy results. • Relevant past medical history, e.g. coeliac disease.
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ULCERATIVE COLITIS
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SUBASH KC/NMC-15TH/2014 Fig. 23.14 Abdominal radiograph showing grossly thickened wall of the transverse colon, with characteristic ‘thumb-printing’.
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Infective colitis Aetiology: bacterial (Salmonella, Shigella, Campylobacter, E. coli), protozoal (Amoebiasis) and viral (herpes and Cytomegalovirus). Increasing incidence in UK due to rise in foreign travel and use of broad-spectrum antibiotics (pseudomembranous colitis).
Clinical presentation Diarrhoea, which may be bloody, non-specific abdominal pain, and pyrexia, associated with anorexia, malaise, and dehydration. Hypotension, tachycardia, and impaired renal function are indicators of severity.
Imaging Stool MC&S is the investigation of choice for diagnosing infective colitis with blood tests used to aid assessment of severity. Sigmoidoscopy/colonoscopy are first-line imaging techniques, as they are more sensitive than radiological investigations for mucosal changes of ulceration and haemorrhage, and to permit biopsy. Radiology is reserved for assessing the extent and severity of disease and to identify complications. Plain film Initial investigation for complications, e.g. colonic dilatation and toxic megacolon (fulminant colitis) or perforation.
SUBASH KC/NMC-15TH/2014 CT (Fig. 23.15) Disease extent can be appreciated on CT which may range from a localized process to a pancolitis. Toxic megacolon and colonic perforation can be accurately identified in addition to further complications such as intra-abdominal collections and liver abscesses. Ultrasound Alternative to CT for identification of liver abscesses and performing percutaneous intervention. Identification of bowel wall thickening may be possible.
Information for the radiologist Stool specimen analysis is paramount. Results of additional investigations such as plain radiographs or colonoscopy. Reasons for further investigation need to be explained. Patients may need to be imaged at the end of the list due to the infection risk.
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INFECTIVE COLITIS
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Fig. 23.15 Axial CT showing diffusely thickened colon, in keeping with colitis in a patient with Clostridium difficile infection.
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Small bowel obstruction ~20% of acute surgical admissions. Subdivided into partial or complete, simple or strangulated. If not diagnosed promptly, vascular compromise can lead to bowel ischaemia, with high mortality. The leading cause in developed countries is postoperative adhesions, other causes include hernia, tumour, inflammatory bowel disease, and volvulus.
Clinical presentation Four cardinal features are pain, vomiting, distension and constipation. Obstruction of bowel leads to proximal dilatation secondary to accumulation of gastrointestinal secretions and swallowed air. This leads to increased peristalsis both proximal and distal to the obstruction, with initial frequent loose stools and flatus. Increasing small-bowel distension leads to increased intraluminal pressures. Vomiting occurs if obstruction is proximal. Constipation occurs as normal transit of bowel contents is not possible (may be absent early).
Imaging Plain film • Abdominal x-ray (Fig. 23.16a): dilated loops of small bowel (>2.5cm) ± air fluid levels, identified by their central position and presence of valvulae conniventes. Gas trapped in the valvulae (string of pearls sign) may also be identified. Depending on degree of obstruction, there may be paucity of gas throughout the colon. Cause/complications of SBO may be identified, e.g. hernia, perforation, or ischaemia. • Erect CXR: if there is any suspicion of perforation.
SUBASH KC/NMC-15TH/2014 CT (Fig. 23.16b) Confirms the presence, severity and cause of obstruction. Diagnosis is by identifying dilated loops of small bowel and a transition point with collapsed loops of distal bowel, excluding ileus. Complications of obstruction such as ischaemia or perforation can be identified.
Information for the radiologist • Relevant medical history, e.g. previous operations, hernia. • Any clinical evidence of developing ischaemia?
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SMALL BOWEL OBSTRUCTION
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(b) Fig. 23.16 a) Abdominal X-ray showing gas-filled loops of centrally-placed, dilated small bowel. b) Coronal CT showing dilated fluid-filled small bowel loops, secondary to an obstructed left inguinal hernia (arrow).
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Large bowel obstruction Obstruction may be luminal, within the bowel wall or extraluminal. Leftsided obstruction >right. Common causes include tumour, abscess, diverticular disease, volvulus, and extrinsic compression from pelvic tumour.
Clinical presentation Features of obstruction: pain, vomiting, distension, and constipation. These features may vary according to the location, age, underlying pathology, or presence of ischaemia. The more distal the obstruction, the longer the interval between onset of symptoms and appearance of nausea and vomiting.
Imaging Plain film (Fig. 23.17a) Supine abdominal X-ray: dilated loops of gas-filled large bowel, recognized by their peripheral position and presence of haustral folds. In a minority of patients the ileocaecal valve is competent and in spite of increasing colonic pressure, the small bowel is not distended. When the valve is incompetent, the caecum and ascending colon may not be distended and there may be marked small bowel distension. CT (Fig. 23.17b) Confirms the presence of a mechanical obstruction and to look for the underlying cause. In the presence of a tumour it may be used to plan for surgical treatment. Complications of obstruction such as perforation or ischaemia can also be identified.
SUBASH KC/NMC-15TH/2014 Fluoroscopy Water-soluble enema can be performed to confirm the presence of mechanical obstruction/exclude pseudo-obstruction/ileus, although its role is second line to CT.
Information for the radiologist • Relevant medical history, e.g. oncological disease/previous sigmoid volvulus. • Whether there is clinical evidence of developing ischaemia.
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LARGE BOWEL OBSTRUCTION
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(a)
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(b) Fig. 23.17 a) Abdominal radiograph showing dilated loops of large and small bowel, secondary to an obstructing distal colonic tumour. b) Coronal CT showing the obstructing tumour (arrow).
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Paralytic ileus and pseudo-obstruction Paralytic ileus occurs when intestinal peristalsis ceases and there is an accumulation of fluid and gas in the bowel, leading to non-specific dilatation of both small and large bowel mimicking obstruction. Causes include postoperative ileus, electrolyte disturbance, and peritonitis. A localized small bowel ileus affecting only 1 or 2 adjacent loops (‘sentinel loops’) can occur in response to a local inflammatory process, such as acute pancreatitis. Pseudo-obstruction refers to large bowel distention resulting from chronic impairment of motility. Patients are usually elderly, often on anticholinergics. The degree of colonic distension may be severe enough to cause caecal perforation. Surgical intervention is occasionally necessary.
Clinical presentation Paralytic ileus and pseudo-obstruction present with abdominal distension, usually without pain (unlike in mechanical obstruction). Patients may or may not continue to pass flatus and stool.
Imaging Plain film (Fig. 23.18a) In paralytic ileus, distended small and large bowel loops are seen with the degree of distension varying from local dilatation of a short length of bowel to distension of the entire intestine. When there is generalized bowel distension, the appearances cannot usually be distinguished on plain radiograph alone from low grade large bowel obstruction. In pseudo-obstruction, the large bowel is dilated all the way to the rectum, and the small bowel may be distended as well. The caecum may exceed the critical diameter of 9cm when perforation is imminent.
SUBASH KC/NMC-15TH/2014 CT (Fig. 23.18b) This is sometimes required to exclude mechanical obstruction and to prevent unnecessary surgery. Fluoroscopy Water-soluble enema may be required to exclude mechanical obstruction, but CT is usually the preferred method of investigation.
Information for the radiologist • Presenting symptoms and signs. • Any recent surgery.
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PARALYTIC ILEUS AND PSEUDO-OBSTRUCTION
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(a)
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(b) Fig. 23.18 a) Abdominal X-ray showing prominent gas-filled loops of small bowel, with a normal gas pattern in the large bowel, in keeping with ileus. b) Coronal CT from the same patient showing fluid-filled loops of small bowel, with no transition point to collapsed bowel. Normal faeces and gas within the large bowel. This is in keeping with ileus.
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Gastrointestinal perforation Complete penetration of the wall of the oesophagus, stomach, or bowel, resulting in the intestinal contents in the thorax or abdomen, depending on the site of perforation. Potentially a surgical emergency. Intestinal perforation results in bacterial contamination of the abdominal cavity, gastric perforation can lead to a chemical peritonitis. Causes: iatrogenic (following a procedure, e.g. endoscopy/colonoscopy), spontaneous (duodenal ulcer, appendicitis, diverticulitis, tumour), traumatic.
Clinical presentation These depend on the site of perforation: • Chest pain/dysphagia (if oesophageal). • Severe abdominal pain/rigidity (due to peritonitis). • Sepsis (depending on organ which has perforated).
Imaging Plain film • Erect CXR (Fig. 23.19): pneumoperitoneum or pneumomediastinum, pleural effusion, subcutaneous emphysema of the neck. • Supine abdominal X-ray: Rigler’s sign (gas on both sides of the bowel wall), or outlining of the falciform ligament. In infants, free gas collects centrally producing a rounded translucency (football sign).
SUBASH KC/NMC-15TH/2014 CT More sensitive at identifying free gas and suggesting its origin—large amounts of free gas suggest perforation of large bowel, large amounts of fluid indicate a small bowel perforation. May see oral contrast extravasation. Fluoroscopy Used less now as increased use of CT. Water soluble contrast studies: • Swallow (for suspected oesophageal perforation). • Enema (for lower GI perforation/to check anastomotic sites post lower GI surgery).
Information for the radiologist • History of recent procedures, e.g. endoscopy. • Whether patient is able to take oral preparation (for CT).
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GASTROINTESTINAL PERFORATION
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SUBASH KC/NMC-15TH/2014 Fig. 23.19 Erect CXR showing free gas under the diaphragm in a patient with perforated duodenal ulcer.
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Subphrenic abscess Majority occur following surgery, and high mortality associated with these abscesses can be reduced by their early diagnosis and management. The subphrenic space extends from the diaphragm above to the transverse mesocolon below and can be divided into 2: • Left subphrenic space: the commonest cause is following operation on the stomach, the tail of pancreas, the spleen, or splenic flexure of the colon. • Right subphrenic space: common causes are perforating cholecystitis, perforated duodenal ulcer, and appendicitis.
Clinical presentation Signs and symptoms are frequently non-specific and may include: • Swinging pyrexia, wasting, and anorexia. • Epigastric fullness and tenderness. • Shoulder pain (referred due to irritation of the phrenic nerve). • Persistent hiccups.
Imaging Plain film • Erect CXR: pneumoperitoneum or a pleural effusion, elevation or tenting of the diaphragm, basal consolidation on side of abscess. • Abdominal X-ray: gas/fluid level adjacent to the diaphragm, an irregular pocket of gas or a soft tissue mass. Secondary paralytic ileus may also be seen.
SUBASH KC/NMC-15TH/2014 Ultrasound (Fig. 23.20a) Particularly valuable in detection of gas-free abscesses, also used to guide the insertion of a drain for treatment. CT (Fig. 23.20b) Allows identification of the abscess/assessment of the other abdominal organs or further collections. CT can also be used to guide drainage.
Information for the radiologist History/details of any previous operations, dates of previous drainages, clotting result.
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SUBPHRENIC ABSCESS
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(a)
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(b) Fig. 23.20 a) Ultrasound image showing fluid collection overlying the liver, beneath the diaphragm (arrows). b) Coronal CT showing right-sided subphrenic abscess, seen as fluid attenuation below the diaphragm (arrows).
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Diverticular disease Diverticula develop when the mucosa herniates through points of weakness in the muscle layers of the colon wall at sites of vascular penetration. • Diverticulosis = the presence of colonic diverticula. • Diverticulitis = when inflammation is present. • Sigmoid colon is the most common site. Only 15% of patients have right-sided diverticulosis.
Clinical presentation Prevalence increases with age, although most remain asymptomatic. It is commonly an incidental finding. Causes include changes in colonic wall resistance, disordered motility, and reduced dietary fibre intake.
Imaging • Role is to establish the diagnosis, severity, and extent. • Confirm active inflammation in diverticulitis. • Identify any complications—abscess, perforation, fistula formation, haemorrhage. Fluoroscopy—barium enema • Traditional test, CT, however, now often first line. • Air/barium filled outpouchings extending from the lumen. • Stricture length and calibre malignant stricture must be excluded. Features in favour of diverticular stricture include: • Stricture >10cm. • Intact mucosa. • Adjacent diverticula (may also coexist with tumour). • Smooth transition with normal colon cf. shouldered margins of malignant stricture (‘apple core lesion’).
SUBASH KC/NMC-15TH/2014 CT (Fig. 23.21) • Thickened bowel wall >3mm, with inflammation. • Abscess formation: gas/fluid collection. • Free intraperitoneal air/localized locules = perforation. • Fistulation: 65% of colovesical fistulae occur as a result of diverticular disease (differential diagnosis is malignancy and Crohn’s disease). • CT angiography is used in active bleeding.
Information for the radiologist Accurate clinical history, with attention to features suggesting bleeding, malignancy, fistula, etc. Sigmoidoscopy findings.
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Fig. 23.21 Axial CT image showing a length of thickened sigmoid colon, with diverticulitis, pericolonic inflammatory change, and locules of pericolonic gas.
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Volvulus • Twisting of a segment of bowel with subsequent obstruction. The sigmoid colon and caecum are most commonly affected due to the long, mobile mesentery. • Risk factors: increased age (caecal younger 30–60 years), chronic constipation, mental handicap, institutionalization.
Clinical presentation • Sigmoid: lower abdominal pain and progressive abdominal distension, may be spontaneously relieved by passage of a large amount of flatus/ faeces, may develop complete obstruction. • Caecal: symptoms are those of acute bowel obstruction including pain, distension, and vomiting. Treatment is with decompression via a rectal tube through the twisted segment (sigmoid), surgical resection of redundant loop sometimes required. Unrelieved obstruction may lead to bowel infarction/perforation.
Imaging Plain film • Sigmoid: bowel loop dilated to occupy the whole abdomen, with the appearance of an inverted ‘U’ (resembling a ‘coffee bean’). Sigmoid loop typically devoid of haustra, with apex on the left of the abdomen. Remaining large bowel is often dilated, which is not seen in caecal volvulus. • Caecal: caecum usually twists and inverts so the caecal pole occupies the left upper quadrant. The attached gas-filled appendix is sometimes seen. 1 or 2 haustral markings can still be seen. Often marked gaseous or fluid distension of small bowel. The left colon is usually collapsed.
SUBASH KC/NMC-15TH/2014 CT Performed when clinical and plain film assessment is inconclusive. As well as the signs previously described on plain film, the ‘whirl sign’ on CT reflects the twisted bowel and mesentery, along with demonstration of complications such as ischaemia and perforation. Fluoroscopy If diagnostic doubt, a water-soluble contrast enema can be performed (risk of perforation contraindicates the use of barium). Features at the point of torsion include a smooth, curved tapering of the colonic lumen to give a ‘bird’s beak appearance’, although CT increasingly used as first line.
Information for the radiologist • Presenting symptoms and signs, any clinical suspicion of ischaemia.
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SUBASH KC/NMC-15TH/2014 Fig. 23.22 Abdominal X-ray showing grossly dilated loop of large bowel within the left abdomen in a patient with sigmoid volvulus.
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Gastrointestinal conditions
Intussusception Intussusception is the telescoping, or prolapse of one part of bowel into an adjacent segment. The prolapsed segment is referred to as the intussusceptum and the receiving segment is the intussuscipiens. The most common sites are ileo–colic and ileo–ileo–colic.
Clinical presentation Commonest in children 3 months–3 years. Majority are idiopathic with no lead point other than lymphoid hyperplasia. In adults 90% have a leadpoint including lymphoma, polyps, tumours, Meckel’s diverticulum, etc. In children, presenting features are of intermittent colicky pain with drawing up of the legs with or without vomiting. The child may be completely well between episodes. Initially there may be watery stools but later the patient may pass blood and mucus in the classically described ‘redcurrant jelly stools’. In late presentations, there may be features of bowel obstruction and shock, with possible ischaemia. In adults, abdominal pain, nausea and vomiting are common over weeks–months.
Imaging Plain film Abdominal X-ray normal in 50%. Classic findings include a soft tissue mass (most commonly in the right upper quadrant) and air crescent sign outlining the apex of the intussusceptum.
SUBASH KC/NMC-15TH/2014 Ultrasound (Fig. 23.23a) First-line investigation for intussusception. Free fluid is a common finding and does not preclude air enema.
CT (Fig. 23.23b) In adults, CT is usually the first investigation, and may reveal the lead point. Fluoroscopy Single contrast/air enema demonstrates the obstruction, and reduction with air enema is the mainstay of treatment in uncomplicated paediatric intussusception. Air reduction should only be carried out in a centre with paediatric surgery and the child must be adequately resuscitated and haemodynamically stable. An NG tube is advised to decompress the stomach. Absolute contraindications are peritonism, perforation, or persisting shock. There is no role for this in adults.
Information for the radiologist Predisposing conditions, duration of symptoms, and clinical condition of the patient.
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(a)
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(b) Fig. 23.23 a) Ultrasound image showing ‘doughnut’ appearance in a 2-year-old with intussusception. b) Axial CT showing intussuscepting loop of bowel within the right flank, giving the typical ‘bowel within bowel’ appearance.
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Acute pancreatitis Around 80% mild and self-limiting, 20% severe, associated with pancreatic necrosis and marked systemic response, may lead to multi organ failure. Causes: alcohol, gallstones, iatrogenic (post ERCP), drugs, trauma, metabolic e.g. increased Ca2+, infection, congenital (pancreas divisum/annular pancreas), tumour, idiopathic. Pathophysiology: unregulated activation of pancreatic enzymes leads to autodigestion of the gland causing inflammation and necrosis. Leakage of enzymes into the surrounding structures causes local complications.
Clinical presentation Epigastric/central abdominal pain. Vomiting.
Imaging • Confirm diagnosis and identify cause. • Assess severity of pancreatitis, progression and complications. • Guide interventional procedures, e.g. drainage of peripancreatic abscess. Ultrasound Detects gallstones. Pancreas often obscured by body habitus and bowel gas.
SUBASH KC/NMC-15TH/2014 CT (Fig. 23.24) Triple phase CT is the imaging modality of choice. CT 24 hours prior to any planned ascitic tap or drain insertion.
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(a)
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(b) Fig. 23.27 a) Ultrasound image of the abdomen in a patient with liver disease showing free intraperitoneal fluid. b) Coronal CT from a different patient showing widespread intra-abdominal fluid, secondary to primary peritoneal carcinomatosis.
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Hernia The protrusion of a viscus/part of a viscus from the cavity in which it is normally contained. Most hernia occur in the abdomen. Hernias are irreducible if they cannot be pushed back into the right place. Incarcerated hernias are no longer reducible. Obstruction means that bowel contents can’t pass through the hernia. Strangulated hernia occur when the vascular supply is compromised. Inguinal: commonest type, men >women. For a full list of hernia types, see b OHCM, p614.
Clinical presentation Generally asymptomatic—may complain of a fullness at the hernia site, aching, or the lump may enlarge on increasing intra-abdominal pressure/standing. If the hernia becomes incarcerated, there may be enlargement of the hernia, and it may become obstructed. Strangulated hernia may present with systemic toxicity secondary to ischaemic bowel.
Imaging Plain film An inguinal hernia may be identified, but this isn’t sensitive or specific. Useful if present with a small bowel obstruction. Ultrasound Increasingly used in the outpatient investigation of groin pain to confirm the presence of a groin hernia if equivocal examination. This has replaced herniography.
SUBASH KC/NMC-15TH/2014 CT May be helpful to diagnose spigelian or obturator hernia, or if unable to examine the patient due to body habitus, and ultrasound failed.
Information for the radiologist Any signs of ischaemic compromise clinically.
Fig. 23.28 Axial CT scan showing dilated loops of fluid-filled obstructed small bowel, secondary to a right-sided groin hernia (arrow).
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Chapter 24
Breast differential diagnosis Gynaecomastia 414 Solitary lesion at mammography 414 Multiple lesions at mammography 414
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Breast differential diagnosis
Gynaecomastia Abnormal amount of breast tissue in men. • Physiological. • Drugs: • Oestrogen, anti-androgens, etc. • Pathological: • Hypogonadism. • Cirrhosis. • Hyperthyroidism. • Tumours: oestrogen producing, e.g. testicular; HCG producing, e.g. testicular, bronchial cancers.
Solitary lesion at mammography Malignant: • Carcinoma. • Phyllodes tumour. Benign: • Cyst. • Fibroadenoma. • Intramammary lymph node. • Galactocoele. • Papilloma. • Abscess.
SUBASH KC/NMC-15TH/2014 Multiple lesions at mammography • • • • •
Cysts. Fibroadenomas. Skin lesions, e.g. neurofibromas. Intramammary lymph nodes. Metastases.
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Breast conditions Mammography 416 Breast cancer 418 Breast abscess 422 Breast cyst 424 Fibroadenoma 426 Papilloma 428
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Breast conditions
Mammography A mammogram is an X-ray examination of the breast. It is a highly effective imaging method for detecting, diagnosing, and managing a variety of breast diseases, especially cancer.
Indications 1. Evaluation of breast symptoms as part of triple assessment Females may present with symptoms such as a breast lump, pain, nipple thickening or discharge, skin or nipple retraction, or a change in breast size and shape. Symptomatic females have a mammogram and ultrasound as appropriate depending on the clinical presentation. However, young women have higher breast parenchymal density, making it difficult to differentiate between tumour and normal breast tissue on mammography. Ultrasound is more sensitive than mammography in young women and is the first-line investigation in women aged 5mm, thickened cortex >2mm, or complete loss of the central fatty hilum. Lymph nodes with malignant or suspicious features require fine needle aspiration cytology. If the lymph nodes are confirmed to be positive for metastatic disease on cytology, the patient will undergo axillary clearance. If the nodes are negative, then the patient will have sentinel node biopsy at the time of surgery.
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MRI Contrast-enhanced MRI highlights neovascularity in malignant lesions that demonstrate rapid uptake and washout of contrast. It is utilized selectively to aid local staging in patients who have tumours that are difficult to accurately size both clinically and with routine imaging. In particular, lobular carcinoma has a propensity for multifocality and defining the true extent of disease is vital. If the tumour proves too large for breast conserving surgery (wide local excision), then a mastectomy is necessary. In addition, MRI is used to assess the response to neoadjuvant chemotherapy and the detection of recurrence in the post-surgical breast. CT Complete staging with CT of the thorax, abdomen, and pelvis is performed in patients with malignant involvement of the axillary lymph nodes or features suspicious for metastatic spread.
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(b)
Fig. 25.2 a) and b) Spiculate mass seen in the 12 o’clock position of the right breast.
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Fig. 25.3 Ultrasound image demonstrating an irregular hypoechoic mass at the 12 o’clock position of the right breast, with extensive posterior shadowing.
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Bone scan Bone metastases are the most common site of distant spread in breast cancer. Bone scan is used routinely in patients with involved axillary nodes or with bone pain. Image-guided biopsy All indeterminate to malignant lesions in the breast require needle core biopsy for histological confirmation. This can be performed clinically but increasingly biopsies are done under imaging control because this is more accurate. If the mass can be localized with ultrasound, this is the preferred imaging modality as it is the quickest technique with real-time visualization of the needle sampling the mass. However, if the lesion can only be seen with mammography, then X-ray-guided biopsy is utilized. MRI-guided biopsy is performed if the mass is occult on both mammography and ultrasound. This technique is only available in specialist centres and is very time consuming.
Information for the radiologist Relevant risk factors including the patient’s age, personal history of breast cancer and positive family history. The clinical score (P1 = normal, P2 = benign, P3 = indeterminate, P4 = suspicious for malignancy, P5 = malignant) is vital to ensure appropriate correlation with imaging findings. The presence of chronic kidney disease (GFR 35 years of age once the acute infection has resolved to rule out an underlying malignancy.
Ultrasound The skin appears thickened with pockets of fluid between the skin and subcutaneous tissue consistent with oedema. An abscess can have a varied appearance (Fig. 25.4). At one end of the spectrum, it can appear cystic in nature with low level internal echoes. In certain cases, it can appear more complex resembling a solid, hypoechoic mass. If the infectious process does not resolve with antibiotics, then ultrasound-guided aspiration of the abscess is helpful.
Information for the radiologist Is the patient currently breastfeeding? If they have been treated with antibiotics, has there been a positive response? If not, is ultrasound guided aspiration required? The clinical score (P1 = normal, P2 = benign, P3 = indeterminate, P4 = suspicious for malignancy, P5 = malignant) is vital to ensure appropriate correlation with imaging findings.
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Fig. 25.4 Ultrasound image demonstrating a mixed solid/cystic lesion consistent with an abscess.
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Breast cyst Cysts arise in the terminal ductal lobular unit as a result of an imbalance between the production and resorption of secretions. Often, cysts are multiple and bilateral. Cysts are common in the perimenopausal years, with a peak incidence between the ages of 40 and 50 years. In younger lactating females, the cysts may be filled with milk and termed a galactocoele. Simple cysts are not associated with malignancy.
Clinical presentation One or several palpable smooth, fluctuant, benign feeling lumps. Occasionally, a tense cyst can present as a discrete hard mass.
Imaging Mammography A cyst appears as a well-defined, round or oval mass (Fig. 25.5). Sometimes a thin lucent halo is seen surrounding the mass. Occasionally, fine curvilinear ‘eggshell’ calcification is seen in the cyst wall. A galactocoele that has sufficient fat content may be visible as a radiolucent mass or even demonstrate a fat-fluid level in upright lateral mammograms. These features are not specific and ultrasound imaging is necessary to evaluate if the mass is solid or a fluid-filled cyst. Ultrasound A simple cyst has well-defined margin (Fig. 25.6). It has no internal echoes and there is increased through transmission of the ultrasound beam reflecting its fluid content. A galactocoele can look like a simple cyst or occasionally have low level internal echoes due to the fat content (Fig. 25.7). Features of a complex cyst include the presence of internal echoes, thin septations or a thickened irregular wall. A cyst may be aspirated if the patient is symptomatic or if there is any diagnostic uncertainty. Fluid is sent for cytology only if blood-stained or if there are atypical sonographic features.
SUBASH KC/NMC-15TH/2014 Information for the radiologist It is useful to document if lactating. Relevant risk factors including the patient’s age, personal history of breast cancer, and positive family history. The clinical score (P1 = normal, P2 = benign, P3 = indeterminate, P4 = suspicious for malignancy, P5 = malignant) is vital to ensure appropriate correlation with imaging findings.
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(b)
Fig. 25.5 a) MLO projection and b) CC projections of the right breast demonstrating a well-defined mass in the upper outer quadrant of the right breast.
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Fig. 25.6 Ultrasound demonstrating a well-defined simple cyst with posterior acoustic enhancement.
Fig. 25.7 Ultrasound demonstrating thick walled cyst with internal echoes in keeping with a galactocoele.
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Fibroadenoma A fibroadenoma is the result of idiopathic overgowth of the specialized stromal connective tissue within the breast lobule. It is the most common cause of a benign solid mass in the breast. In the majority of cases they are solitary, but in 20% of females they can be multiple. Fibroadenomas are hormone sensitive and tend to increase in size during pregnancy and involute in the perimenopausal period. Peak incidence is in the 3rd decade.
Clinical presentation Fibroadenomas present clinically as a smooth, firm, mobile mass. It is sometimes referred to as a ‘breast mouse’ because of its mobility within the breast tissue.
Imaging Mammography A fibroadenoma is seen as a well-circumscribed, oval mass. Sometimes a thin, lucent halo is seen surrounding the mass. In older women, as the fibroadenoma involutes, coarse ‘popcorn’ calcification may be seen associated with the mass. Ultrasound It is seen as a well-defined, ovoid, hypoechoic mass with a thin echogenic pseudocapsule (Fig. 25.8). As the tumour grows along tissue planes, it tends to be wider than it is tall. Despite sonographic features consistent with benign disease, needle core biopsy for histological diagnosis is performed either clinically or under direct vision with ultrasound guidance. This is necessary to ensure that well-circumscribed cancers are not missed. Once a benign histological diagnosis is obtained, no further intervention is required.
SUBASH KC/NMC-15TH/2014 Information for the radiologist Relevant risk factors including the patient’s age, personal history of breast cancer, and positive family history. The clinical score (P1 = normal, P2 = benign, P3 = indeterminate, P4 = suspicious for malignancy, P5 = malignant) is vital to ensure appropriate correlation with imaging findings.
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SUBASH KC/NMC-15TH/2014 Fig. 25.8 Ultrasound demonstrating a well-defined solid hypoechoic mass with a thin echogenic capsule in keeping with a fibroadenoma.
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Papilloma A papilloma is a tumour that arises in a duct, either centrally or peripherally within the breast. It represents a focal proliferation of the ductal epithelium that projects into the lumen of the duct. Papillomas are largely considered benign lesions, especially if solitary within a large subareolar duct. Multiple papillomas tend to be within smaller, peripheral ducts and are associated with an increased likelihood of atypia and malignancy.
Clinical presentation Papillomas are associated with overproduction of secretions that are not balanced by the normal resorptive mechanisms of the duct. This results in distension of the duct and nipple discharge. As they are friable structures that bleed easily, the nipple discharge may be blood-stained. Occasionally, a palpable mass is evident.
Imaging Mammography Papillomas are often not appreciated on mammography due to their small size and intraductal location. When imaging findings are present, they include a well-circumscribed subareolar mass, solitary or multiple dilated ducts, and infrequently a cluster of microcalcifications. Ultrasound Characteristically, papillomas appear as a hypoechoic, lobulated mass within a dilated duct or cyst (Figs. 25.9 and 25.10). Due to the association with malignancy, needle core biopsy under ultrasound guidance is performed for histological diagnosis. If there are no features of atypia, it can be removed percutaneously with a vacuum-assisted biopsy device. If there are features of atypia, then surgical excision is necessary.
SUBASH KC/NMC-15TH/2014 Information for the radiologist If there is nipple discharge, is it blood-stained? Relevant risk factors including the patient’s age, personal history of breast cancer, and positive family history. If there is a palpable mass, the clinical score (P1 = normal, P2 = benign, P3 = indeterminate, P4 = suspicious for malignancy, P5 = malignant) is vital to ensure appropriate correlation with imaging findings.
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Fig. 25.9 Ultrasound image demonstrating 7mm solid papilloma seen projecting into the lumen of the cyst.
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(a)
(b) Fig. 25.10 a) and b) Ultrasound images demonstrating 6mm papilloma seen sitting within a dilated duct.
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Index A abdominal aortic aneurysm 122–3 abdominal calcification 342 abdominal distension 355 abdominal pain 346 abdominal trauma 320–1 abdominal ultrasound 8 achalasia 374–5 acoustic neuroma 154–5 acromio-clavicular joint subluxation/ dislocation 324–5 acute disseminated encephalomyelitis (ADEM) 148 acute myocardial infarction 106–7 acute pancreatitis 404–5 acute pelvic pain 204 acute pyelonephritis 236 acute renal failure 207 acyanotic heart disease 116 adrenal calcification 201 adrenal masses 232, s16.f 9 ALARM symptoms 380 alkaptonuria 270 altered consciousness 138 anaemia, iron deficiency 353 aneurysmal bone cysts 296–7 angiography 6; see also coronary angiography; pulmonary angiography acoustic neuroma 154 acutely painful blue leg 99 aortic stenosis 112 cardiomyopathy 109 coarctation of aorta 110 complications 7 contrast agents 6 glioma 156 hypertension 210 indications 6 intermittent claudication 98 melaena 352 meningioma 158 mitral valve disease 115 pelvic pain, chronic 206 peripheral vascular disease 7, 124 procedure 6 thoracic trauma 318 vascular interventions 20–1
angiomyolipoma 234–5 ankle–brachial pressure index 124 ankle fracture classification system 337 ankle trauma 3, 336–7 ankylosing spondylitis 272–3 anterior humeral line 326 aortic coarctation 110–11 aortic dissection 102–3 aortic stenosis 112–13 appendicitis 376–7 apple-core deformity 362, 364 arteriography 29 arteriovenous fistula 130–1 asbestos exposure benign lung disease 84–5 mesothelioma 88–9 ascites 342, 410–11 astrocytoma 156 atelectasis 64 avascular necrosis 304–5
diaphyseal benign tumours 298–9 metastases 292–3 moth-eaten 258 pain 260 sclerotic lesions 300–1 tumours 263, 290–1 bone scan 13–14 avascular necrosis 304 bone metastases 292 bone pain 260 bone tumours 263, 290 breast cancer 420 diaphyseal benign bone tumours 298 increased uptake 258 myeloma 294 osteomalacia 308 osteomyelitis 278 Paget’s disease 302 prostate cancer 222 proximal femoral fractures 332 renal cell cancer 218 superscan appearance 308 Bosniak classification system 234 Boutonniere deformity 268 bowel, see large bowel; small bowel brain abscess 150–1 brain metastases 160–1 branchial cleft cysts 196–8 Branham’s sign 130 breast; see also mammography abscess 422–3 cancer 418–19 cyst 424–5 differential diagnosis 413 fibroadenoma 426–7 needle core biopsy 420 NHS Breast Screening Programme 416 papilloma 428–9 triple assessment 416 bronchiectasis 70–1 Brown’s tumours 184
SUBASH KC/NMC-15TH/2014 B bamboo spine 272 bare orbit 170 barium examination 4; see also double contrast barium enema achalasia 374–5 colonic cancer 362 diarrhoea 354 diverticular disease 398 gastrointestinal lymphoma 366 iron deficiency anaemia 353 systemic sclerosis 78 weight loss 356 wheeze 31 becquerels 14 Bennett’s fracturedislocation 329 beta-decay 16 bird’s beak oesophagus 374–5 bladder cancer 216–17 bladder filling defects 200 Boehler’s angle 338 bone avascular necrosis 304–5 benign lesions 296–7 cysts 296–7
C caecal volvulus 400 calcaneal fractures 338–9 calcium pyrophosphate deposition disease 270
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INDEX cancer bladder 216–17 breast 418–19 cervical 224–5 colonic 362–3 endometrial 226–7 gastric 360–1 hepatocellular 368–9 laryngeal 180–1 lung 17, 62–3 oesophageal 358–9 ovarian 228, 231 pancreatic 372–3 prostate 222–3 rectal 364–5 renal cell 218–19 testicular 220–1 thyroid 182 urothelial 216–17 carbon dioxide contrast 6 cardiac catheterization 116 cardiac CT congenital heart disease 116 ischaemic heart disease 118 cardiac MRI 117 cardiac tumours 120–1 cardiac ultrasound 9; see also echocardiography cardiomegaly 25, 94 cardiomyopathy 108–9 carpal fracture 328 cartilage injuries, wrist 328 cauda equina syndrome 274 cerebellopontine angle mass 135 cervical cancer 224–5 Charcot foot 286 Charcot’s triad 378 chest pain 28–9 chest radiograph acutely painful blue leg 99 aortic dissection 102 aortic stenosis 112–13 asbestos-related benign lung disease 84–5 bronchiectasis 70–1 cardiomyopathy 108–9 chest pain 28 coarctation of aorta 110–11 congenital heart disease 116–17 connective tissue disease 78–9 COPD 46–7 cystic fibrosis 3, 72–3 emphysema 46–7 gastrointestinal lymphoma 366 hypertension 210 hypoxia 38
interstitial lung disease 76–7 ischaemic heart disease 118 left ventricular failure 52–3 lobar collapse 64–9 lung abscess 42–3 lung cancer 62–3 mediastinal masses 90–1 mesothelioma 88 mitral valve disease 114–15 myocardial infarction 106 peripheral vascular disease 124 pleural effusion 74–5 pneumoconiosis 80–1 pneumonia 44–5 pneumothorax 54–5 pulmonary embolism 48 pulmonary hypertension 58–9 rheumatoid lung 78 sarcoidosis 82–3 shortness of breath 32 solitary pulmonary nodule 60–1 subphrenic abscess 396 systemic lupus erythematosus 78 systemic sclerosis 78 thoracic trauma 318 thyroid nodules and masses 182 tuberculosis 86–7 Wegener’s granulomatosis 56–7 weight loss 356 wheeze 30 chest trauma 318–19 cholangiocarcinoma 370–1 cholangitis 378–9 cholecystitis 378–9 chronic obstructive pulmonary disease (COPD) 46–7 chronic pancreatitis 406–7 chronic pelvic pain 206 cirrhosis 408–9 claudication 98, 124 clavicular fracture 324 coal worker’s pneumoconiosis 80–1 coarctation of aorta 110–11 colitis infective 386–7 ulcerative 384–5 collateral ligament injuries 334 Colles’ fracture 328 colonic cancer 362–3 colonic dilatation 342
communicating hydrocephalus 152 computed tomography (CT) 10, 11; see also CT headings abdominal distension 355 abdominal trauma 320–1 acoustic neuroma 154 acutely painful blue leg 99 adrenal masses 232–3 altered consciousness 138 angiomyolipoma 234–5 ankle trauma 336 ankylosing spondylitis 272 aortic dissection 102–3 aortic stenosis 112 appendicitis 376–7 arteriovenous fistula 131 asbestos-related benign lung disease 84–5 ascites 410–11 bladder cancer 216–17 bone cysts 296 bone metastases 292 bone tumours 263, 290 brain abscess 150–1 brain metastases 160 branchial cleft cysts 196 breast cancer 418 bronchiectasis 70–1 calcaneal fractures 338–9 cardiac tumours 120 cardiomyopathy 108 cervical cancer 225 chest pain 28 cholangiocarcinoma 370–1 cholecystitis/ cholangitis 378–9 cirrhosis 408–9 coarctation of aorta 110–11 colonic cancer 362–3 connective tissue disease 78–9 contrast agents 11 COPD 46 cough 34 Crohn’s disease 382 crystal deposition 270 cystic fibrosis 72 degenerative disc disease 274 diaphyseal benign bone tumours 298 diarrhoea 354 discitis 280 diverticular disease 398–9 drawbacks 11 duodenal ulceration 380–1 dysphagia 174 ECG-gated 120
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INDEX emphysema 46 encephalitis 148–9 endometrial cancer 227 epilepsy 166 facial trauma 314–15 gastric cancer 360–1 gastrointestinal lymphoma 366–7 gastrointestinal perforation 394 glioma 156 haemoptysis 36 hand trauma 330 headache 139 head trauma 312–13 hernia 412 hoarse voice 173 hydrocephalus 152–3 hyperparathyroidism 184 hypertension 210 hypoxia 38 infective colitis 386–7 intermenstrual bleeding 211 intermittent claudication 98 interstitial lung disease 76 interventional procedures 20 intussusception 402–3 iron deficiency anaemia 353 jaundice 350 joint replacement, loose/ painful 288 knee injuries 335 large bowel obstruction 390–1 laryngeal carcinoma 180–1 left ventricular failure 52 liver tumours 368–9 lobar collapse 69, 64–7 lung abscess 42–3 lung cancer 62–3 mediastinal masses 90–1 melaena 352 meningioma 158 mesothelioma 88–9 multislice/multidetector scanners 10 myeloma 294–5 myocardial infarction 107 nasopharyngeal tumours 176 neck lumps 172 oesophageal cancer 358–9 oropharyngeal tumours 178 osteomalacia 308 osteomyelitis 278 ovarian cancer 228, 231
ovarian masses 229–30 ovarian torsion 248–9 Paget’s disease 302 pancreatic cancer 372–3 pancreatitis, acute 404–5 pancreatitis, chronic 406 paralytic ileus 392–3 pelvic fractures 322 pelvic inflammatory disease 250 pelvic pain, acute 205 pituitary adenoma 163 pleural effusion 74 pneumoconiosis 80–1 pneumonia 44 pneumothorax 54 postmenopausal bleeding 212 prostate cancer 222 proximal femoral fractures 332 pseudo-obstruction 392 psoas abscess 282 pulmonary hypertension 58 pyelonephritis 236–7 rectal cancer 364 renal cell cancer 218–19 renal failure, acute 207 renal hamartoma 234–5 salivary gland infection 190–1 salivary gland tumours 194–5 sarcoidosis 82–3 sclerotic bone lesions 300–1 shortness of breath 32 shoulder trauma 324 sialolithiasis 192 sinus disease 188–9 small bowel obstruction 388–9 solitary pulmonary nodule 60–1 spinal trauma 316–17 stomach ulceration 380–1 stroke 142–3 subarachnoid haemorrhage 144–5 subdural haemorrhage 146–7 subphrenic abscess 396–7 swollen diabetic foot 286 testicular cancer 220 thoracic aneurysm 104–5 thoracic trauma 318–19 thyroid nodules and masses 182 tuberculosis 86 ulcerative colitis 384 upper abdominal pain 346 volvulus 400
433
vomiting 349 Wegener’s granulomatosis 56 weight loss 356 wheeze 31 conduitograms 4 congenital heart disease 116–17 connective tissue disease 78–9 consciousness 138 consolidation 24 contrast agents 4, 6, 11 cord compression 276–7 coronary angiography chest pain 29 ischaemic heart disease 118 myocardial infarction 106 corticotrophic adenoma 162 cough 34 Courvoisier’s law 372 Crohn’s disease 382–3 cruciate ligament injury 334 crystal deposition 270–1 CT abdomen and pelvis 205 CT angiogram abdominal aortic aneurysm 122–3 peripheral vascular disease 124 subarachnoid haemorrhage 144 CT colonography 362–3 CT coronary angiogram 118 CT KUB acute pelvic pain 205 haematuria 208 renal tract calculi 238–9 CT myelogram cord compression 276 degenerative disc disease 274 CT number 10 CT pulmonary angiography (CTPA) haemoptysis 36 hypoxia 38 pulmonary embolism 48, 50 CT urogram bladder cancer 216–17 haematuria 208 hydronephrosis 209 Cushing’s disease 162 cyanotic heart disease 116 cystic fibrosis 3, 72–3
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INDEX
D Dawson’s fingers 164 degenerative disc disease 274–5 DEXA 306 diabetic foot 286–7 diaphyseal benign bone tumours 298–9 diarrhoea 354 dilated cardiomyopathy 108 discitis 280–1 disc prolapse 274–5 dislocation elbow 326 hip 332 lunate 328 perilunate 328 shoulder 324–5 thumb 329 trans-scaphoidperilunate 328 distal radial fractures 328 diverticular disease 398–9 Doppler ultrasound arteriovenous fistula 130 peripheral vascular disease 124 renal transplant dysfunction 240 stroke 142 double contrast barium enema colonic cancer 362 rectal cancer 364 ulcerative colitis 384 double contrast techniques 4–5 double line sign 304 dual energy X-ray absorptiometry 306 duodenal ulceration 380–1 dural tail sign 158 dysphagia 174
ischaemic heart disease 118 left ventricular failure 52 mitral valve disease 114 myocardial infarction 106 pulmonary embolism 48 pulmonary hypertension 58 ectopic pregnancy 204, 244–5 Eisenmengerization 116 elbow joint effusion 326 elbow trauma 326–7 emphysema 46–7 emphysematous pyelonephritis 236 encephalitis 148–9 endometrial cancer 226–7 endometrial thickness 212 endometriosis 246–7 endoscopic retrograde cholangiopancreatography (ERCP) cholangiocarcinoma 370 cholecystitis/ cholangitis 378 jaundice 351 pancreatic cancer 372 endoscopic ultrasound (EUS) cholangiocarcinoma 370 gastric cancer 360 oesophageal cancer 358 pancreatic cancer 372 pancreatitis, chronic 406 endovascular interventions 126–7, 20–1 ependymoma 156 epididymitis 252–3 epilepsy 166–7 exercise testing 28 exudates 74
achalasia 374–5 aortic dissection 102 cholecystitis/ cholangitis 378 colonic cancer 362 contrast agents 4 cough 34 diverticular disease 398 double contrast techniques 4–5 duodenal ulceration 380 dysphagia 174 gastrointestinal lymphoma 366 gastrointestinal perforation 394 gastro-oesophageal reflux 374 GI radiology 4–5 hiatus hernias 374 intussusception 402 jaundice 351 joint replacement, loose/ painful 288 large bowel obstruction 390 neck lumps 172 oesophageal cancer 358 paralytic ileus 392 pseudo-obstruction 392 rectal cancer 364 stomach ulceration 380 systemic sclerosis 78 thoracic aneurysm 105 ulcerative colitis 384 uro radiology 4 volvulus 400 vomiting 349 weight loss 356 football sign 394 fracture ankle 3, 336–7 Bennett’s fracturedislocation 329 calcaneal 338–9 carpal 328 clavicular 324 Colles’ 328 distal radial 328 elbow 326–7 humeral neck/head 324 malleoli 336 metacarpal 329 neck of femur 332–3 patella 334 pelvic 322–3 phalangeal 329 proximal femoral 332–3 Rolando 329 scaphoid 328 Segond 334 Smith’s 328 talus 336
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E ECG-gated CT 120 ECG-gated MRI 119 echocardiography 9; see also transoesophageal echocardiography aortic stenosis 112 cardiac tumours 120 cardiomyopathy 108 chest pain 28 coarctation of aorta 110 congenital heart disease 116 cough 34 haemoptysis 36 hypertension 210
F facial trauma 314–15 fallen fragment sign 296 FAST scan 320 FAST screen 142 FDG 16 femur fractures 332–3 fibreoptic bronchoscopy 37 fibroadenoma 426–7 fibromuscular dysplasia 210 FIGO staging 224, 226 figure of 3 appearance 110 finger in glove sign 72 Fitz–Hugh–Curtis syndrome 250 fluorodeoxy-D-glucose (FDG) 16 fluoroscopy 4
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INDEX thumb 329 tibial plateau 334 triquetral avulsion fracture 328
G gadolinium contrast 6, 18 galactocoele 424–5 gallstones 350 gamma camera 12 gamma rays 12 gastric cancer 360–1 gastrointestinal conditions 357 gastrointestinal differential diagnosis 341 gastrointestinal fluoroscopy 4–5 gastrointestinal interventions 20 gastrointestinal lymphoma 366–7 gastrointestinal perforation 394–5 gastrointestinal presenting syndromes 345 gastro-oesophageal reflux disease (GORD) 374 genitourinary conditions 215 genitourinary differential diagnosis 199 genitourinary presenting syndromes 203 giant cell tumours 296–7 glioblastoma multiforme 156 glioma 156–7 global cardiomegaly 94 glottic carcinoma 180 Golden S sign 67 gonadotroph cell adenoma 162 gout 270–1 gynaecomastia 414
hepatocellular cancer 368–9 hernia 412 hiatus 374 herpes simplex encephalitis 148 hiatus hernia 374 HIDA scan 350 high resolution computed tomography (HRCT) ankylosing spondylitis 272 bronchiectasis 70–1 haemoptysis 36 hypoxia 38 interstitial lung disease 76 hilar enlargement 26 hip dislocation 332 hoarse voice 173 holly leaf plaques 84 Hounsfield unit 10 humeral neck/head fracture 324 hydrocephalus 152–3 hydrocoele 200 hydronephrosis 9, 207, 209 hyperparathyroidism 184–5 hyperradiancy 25–s2.s 10 hypertension 210 hypertrophic cardiomyopathy 108 hypoparathyroidism 186–7 hypoxia 38 hysterosalpingography 206 hysterosonography 227
435
joint replacement, loose/ painful 288–9 joint swelling 261
K Kerley B lines 26 knee injuries 334–5 knee osteoarthritis 267 Kussmaul’s sign 108
L large bowel obstruction 390–1 large bowel strictures 344 laryngeal carcinoma 180–1 left atrial enlargement 94 left ventricular enlargement 94 left ventricular failure 52–3 leg, painful and blue 99 Legionella pneumonia 44 Lhermitte’s sign 164 ligament injuries collateral ligament 334 cruciate ligament 334 wrist 328 liver cirrhosis 408–9 liver tumours 368–9 lobar collapse 64–9 Lofgren’s syndrome 82 loopograms 4 Looser’s zone 308 lunate dislocation 328 lung abscess 42–3 cancer 17, 62–3 connective tissue disease 78–9 consolidation 24 hilar enlargement 26 hyperradiancy 25–s2.s 10 interstitial disease 76–7 multiple masses 25 small fibrotic 26 solitary mass 24 solitary pulmonary nodule 60–1 upper zone fibrosis 26 lymphoma, gastrointestinal 366–7
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H haematuria 208 haemoptysis 36–7 hand deformities 268–9 hand trauma 328–30 headache 139 head and neck conditions 175 head and neck differential diagnosis 169 head and neck presenting syndromes 171 head trauma 312–13
I infective colitis 386–7 inferior vena cava filters 128–9 intermenstrual bleeding 211 intermittent claudication 98 interstitial lung disease 76–7 interventional radiology 20–1 intracerebral mass 134 intracranial calcification 134 intravenous urogram (IVU) haematuria 208 renal tract calculi 238 intussusception 402–3 iodine-based contrast agents 4, 6, 11 iron deficiency anaemia 353 ischaemic heart disease 118–19
J jaundice 350
M macroadenoma 162 magnetic resonance angiogram (MRA) 125 magnetic resonance cholangiopancreatography (MRCP)
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436
INDEX magnetic resonance cholangiopancreatography (cont.) cholecystitis/ cholangitis 378 jaundice 351 pancreatitis, chronic 406–7 magnetic resonance enterography (MRE) Crohn’s disease 382–3 diarrhoea 354 magnetic resonance imaging (MRI) 18 abdominal aortic aneurysm 122 abdominal distension 355 acoustic neuroma 154–5 acutely painful blue leg 99 adrenal masses 232–3 ankle trauma 336 ankylosing spondylitis 272–3 aortic dissection 102 aortic stenosis 112–13 applications 18 arteriovenous fistula 131 avascular necrosis 304 bladder cancer 216 bone cysts 296 bone metastases 293 bone pain 260 bone tumours 263, 290 brain abscess 150 brain metastases 160–1 branchial cleft cysts 196–7 breast cancer 418 calcaneal fractures 338 cardiac tumours 120–1 cardiomyopathy 108–9 cervical cancer 224, 225 chest pain 29 cholangiocarcinoma 370 cirrhosis 408 coarctation of aorta 110 contraindications 18 cord compression 276–7 crystal deposition 270 degenerative disc disease 274–5 diaphyseal benign bone tumours 298–9 discitis 280–1 dysphagia 174 ECG-gated 119 ectopic pregnancy 244 encephalitis 148 endometrial cancer 227 endometriosis 246 epilepsy 166 glioma 156–7 haemoptysis 36 head trauma 312
hydrocephalus 152 hydronephrosis 209 hyperparathyroidism 184 hypoxia 39 intermenstrual bleeding 211 intermittent claudication 98 joint replacement, loose/ painful 288 knee injuries 335 laryngeal carcinoma 180 left ventricular failure 52 liver tumours 368 lung cancer 62 mediastinal masses 90 meningioma 158–9 mesothelioma 88 mitral valve disease 115 multiple sclerosis 164–5 myeloma 294 nasopharyngeal tumours 176–7 neck lumps 172 oropharyngeal tumours 178–9 osteoarthritis 266 osteomalacia 308 osteomyelitis 278–9 ovarian cancer 228 ovarian masses 230 ovarian torsion 248–9 Paget’s disease 302 pancreatic cancer 372 pancreatitis, acute 404 pancreatitis, chronic 406 pelvic fractures 322 pelvic inflammatory disease 250 pelvic pain, chronic 206 pituitary adenoma 163 postmenopausal bleeding 212 prostate cancer 223 proximal femoral fractures 332 psoas abscess 282–3 pulmonary embolism 49 pulmonary hypertension 58 rectal cancer 364–5 rheumatoid arthritis 268 salivary gland tumours 194–5 sarcoidosis 82 sclerotic bone lesions 300 septic arthritis 284–5 shoulder trauma 324 sialolithiasis 192 sinus disease 188 soft tissue lump 262 solitary pulmonary nodule 60
spinal trauma 316 STIR 19, 280–1 stroke 143 subarachnoid haemorrhage 144 subdural haemorrhage 146 swollen diabetic foot 286 swollen joint 261 testicular cancer 220 thoracic aneurysm 104 thoracic trauma 318 thyroid nodules and masses 182 tuberculosis 19, 87 ulcerative colitis 384 Wegener’s granulomatosis 56 malleoli fractures 336 mallet finger 268 mammography analogue 416 breast abscess 422 breast cancer 418–19 breast cyst 424–5 digital 416 family history surveillance 416 fibroadenoma 426 galactocoele 424 indications 416 mean glandular dose 417 multiple lesions 414 NHS Breast Screening Programme 416 papilloma 428 post-surgical 416 solitary lesion 414 technique 416–17 triple assessment 416 massive haemoptysis 36 maxillary antrum opacification 170 mediastinal masses 90–1 medulloblastoma 156 melaena 352 meningioma 158–9 meniscal injuries 334 mesothelioma 88–9 metacarpal fracture 329 metastases bone 292–3 brain 160–1 liver 368 MIBG scan 120 MIBI scan 118 microadenoma 162 micturating cystourethogram (MCUG) 242–3 millisieverts 14 mitral valve disease 114–15 monophonic wheeze 30 moth-eaten bone 258
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SUBASH KC/NMC-15TH/2014
INDEX mother in law blush 158 MUGA scan 118 multiple-ring enhancing lesions 134 multiple sclerosis 164–5 mumps 190 Murphy’s sign 378 musculoskeletal conditions 265 musculoskeletal differential diagnosis 257 musculoskeletal presenting syndromes 259 myeloma 294–5 myocardial infarction 106–7
N nasopharyngeal mass 170 nasopharyngeal tumours 176–7 neck lumps 172 ultrasound 9 neck of femur fracture 332–3 nephrostomy 207 neurofibromatosis type I/II 154 neurology conditions 141 neurology differential diagnosis 133 neurology presenting syndromes 137 NHS Breast Screening Programme 416 non-communicating hydrocephalus 152 nuclear medicine 15, 12–13 advantages 14 arteriovenous fistula 131 avascular necrosis 304 bone pain 260 bone tumours 263 cardiac tumours 120 chest pain 28 colonic cancer 362 contraindications 14 COPD 46 disadvantages 14 dose 14 dysphagia 174 emphysema 46 gastro-oesophageal reflux 374 haemoptysis 36 hydronephrosis 209 hyperparathyroidism 184–5 hypoxia 39 indications 14 ischaemic heart disease 118
jaundice 350 laryngeal carcinoma 180 left ventricular failure 52 lobar collapse 64 lung cancer 62 mediastinal masses 90 melaena 352 mesothelioma 88 nasopharyngeal tumours 176 neck lumps 172 oropharyngeal tumours 178 osteomalacia 308 patient preparation 14 radionuclides 12 radiopharmaceuticals 12 rectal cancer 364 shortness of breath 32 solitary pulmonary nodule 60 testicular torsion 254 vesico-ureteric reflux 243 vomiting 349 Wegener’s granulomatosis 56
O
437
paralytic ileus 392–3 paranasal sinus absence/ hyperplasia 170 parotid gland infection 190–1 tumours 194–5 patella fractures 334 pelvic fractures 322–3 pelvic inflammatory disease 250–1 pelvic pain acute 204 chronic 206 pelvic ultrasound 8, 204 percutaneous nephrolithotomy 238 perilunate dislocation 328 peripheral vascular disease 124–7,7 PET-CT 16 bone metastases 293 colonic cancer 362 contraindications 17 dysphagia 174 indications 16 laryngeal carcinoma 180 lobar collapse 64 lung cancer 17, 62 nasopharyngeal tumours 176 neck lumps 172 oesophageal tumour 17 oropharyngeal tumours 178 patient preparation 16 rectal cancer 364 technique 16 phaeochromocytoma 232 phalangeal fracture 329 pituitary adenoma 162–3 pixels 10 plain film radiography 2; see also chest radiograph abdominal aortic aneurysm 122 abdominal distension 355 achalasia 374 acoustic neuroma 154 adrenal masses 232 alkaptonuria 270 aneurysmal bone cyst 296 ankle trauma 3, 336–7 ankylosing spondylitis 272–3 appendicitis 376 arteriovenous fistula 130 ascites 410 avascular necrosis 304–5 bone cysts 296–7 bone metastases 292–3 bone pain 260 bone tumours 263, 290–1 brain metastases 160
SUBASH KC/NMC-15TH/2014 oesophageal cancer 17, 358–9 oesophageal strictures 344 oligodendroglioma 156 orbital calcification 170 oropharyngeal tumours 178–9 osteoarthritis 266–7 osteoid osteoma 298 osteomalacia 308–9 osteomeatal complex 188 osteomyelitis 278–9 osteonecrosis 304–5 osteopenia 258 osteophytes 267 osteoporosis 306–7 osteoporosis circumscripta 302 ovarian cancer 228, 231 ovarian masses 229–30 ovarian torsion 248–9
P Paget’s disease 302–3 pancreatic cancer 372–3 pancreatitis acute 404–5 chronic 406–7 papillary necrosis 236 papilloma (breast) 428–9
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438
INDEX plain film radiography 2 (cont.) caecal volvulus 400 calcaneal fractures 338–9 calcium pyrophosphate deposition disease 270 cardiac tumours 120 colonic cancer 362 cord compression 276 cough 34 crystal deposition 270–1 degenerative disc disease 274 diaphyseal benign bone tumours 298–9 diarrhoea 354 discitis 280 duodenal ulceration 380 dysphagia 174 elbow trauma 326–7 facial trauma 314 gallstones 350 gastrointestinal perforation 394–5 giant cell tumour 296 gout 270–1 haemoptysis 36 hand trauma 328–30 head trauma 312 hernia 412 hiatus hernia 374 hoarse voice 173 hydrocephalus 152 hyperparathyroidism 184 infective colitis 386 intussusception 402 iron deficiency anaemia 353 jaundice 350 joint replacement, loose/painful 288–9 knee injuries 334 large bowel obstruction 390–1 meningioma 158 myeloma 294 oesophageal cancer 358 osteoarthritis 266–7 osteomalacia 308–9 osteomyelitis 278 osteoporosis 306–7 Paget’s disease 302–3 paralytic ileus 392–3 pelvic fractures 322–3 pituitary adenoma 162 prostate cancer 222 proximal femoral fractures 332–3 pseudo-obstruction 392 psoas abscess 282 rectal cancer 364 renal tract calculi 238
rheumatoid arthritis 268–9 sclerotic bone lesions 300 septic arthritis 284 shoulder trauma 324–5 sialolithiasis 192 sigmoid volvulus 400–1 small bowel obstruction 388–9 soft tissue lump 262 spinal trauma 316 stomach ulceration 380 subphrenic abscess 396 swollen diabetic foot 286–7 swollen joint 261 thoracic aneurysm 104 thoracic trauma 318 thyroid nodules and masses 182 ulcerative colitis 384–5 upper abdominal pain 346 volvulus 400–1 vomiting 348 wheeze 30 wrist trauma 328–30 pleural effusion 25, 74–5 pleural malignancy 88–9 pneumatosis intestinalis 343 pneumoconiosis 80–1 pneumonia 44–5 pneumoperitoneum 343 pneumothorax 54–5 polyphonic wheeze 30 positron emission tomography (PET); see also PET-CT adrenal masses 232 cardiac tumours 120 cervical cancer 225 cholangiocarcinoma 370 gastric cancer 360 gastrointestinal lymphoma 366 oesophageal cancer 358 pancreatic cancer 372 solitary pulmonary nodule 60 postmenopausal bleeding 212 primary hyperparathyroidism 184–5 prolactinoma 162 prostate cancer 222–3 proximal femoral fractures 332–3 pseudofractures 308 pseudohypoparathyroidism 186 pseudo-obstruction 392 psoas abscess 282–3 pulmonary angiography chest pain 29
haemoptysis 37 pulmonary embolism 49 pulmonary hypertension 58 pulmonary artery enlargement 95 pulmonary embolism 15, 48–50 pulmonary hypertension 58–9 pulmonary nodule, solitary 60–1 pulmonary plethora 116 pyelonephrosis 236–7
R radiocapitellar line 326 radionuclides 12 radiopharmaceuticals 12 radius, distal fracture 328 rectal cancer 364–5 recurrent laryngeal nerve palsy 173 redcurrant jelly stools 402 reflux 374 renal abscess 234 renal calcification 200 renal cell cancer 218–19 renal cysts 234 renal failure, acute 207 renal hamartoma 234–5 renal masses, benign 234–5 renal tract calculi 238–9 renal transplant dysfunction 240–1 renal tuberculosis 236 renal ultrasound acute pelvic pain 204 hypertension 210 respiratory conditions 41 respiratory differential diagnosis 23 respiratory presenting syndromes 27 rest pain 98 restrictive cardiomyopathy 108 rheumatoid arthritis 268–9 rheumatoid lung 78 rhinosinusitis 188 rib notching 110 rickets 308–9 Rigler’s sign 394 Robson’s staging system 218 Rolando fracture 329 Rovsing’s sign 376
SUBASH KC/NMC-15TH/2014
SUBASH KC/NMC-15TH/2014
INDEX
S sail sign 66 salivary glands calculi 192–3 infection 190–1 tumours 194–5 sarcoidosis 82–3 scaphoid fracture 328 scapholunate ligament injury 329 scintigraphy bladder cancer 216 epilepsy 166 neck lumps 172 thyroid nodules and masses 182 sclerotic bone lesions 300–1 scoliosis 258 Segond fracture 334 septic arthritis 284–5 sequestrum 278 shortness of breath 32 shoulder trauma 324–5 sialography 172, 192–3 sialolithiasis 192–3 sigmoid volvulus 400–1 signet ring sign 70 simple bone cysts 296–7 sinus disease 188–9 sinusitis 188 small bowel dilatation 343 obstruction 388–9 strictures 344 small bowel follow through 354 Smith’s fracture 328 soft tissue lump 262 solitary pulmonary nodule 60–1 somatotrophic adenoma 162 SPECT 185, 304 spinal cord compression 276–7 spinal red flags 280 spinal trauma 316–17 stents 21, 126 STIR 19, 280–1 stomach ulceration 380–1 strictures 344 stridor 30 string of beads sign 210 string of pearl sign 248 stroke 142–3 subarachnoid haemorrhage 144–5 subdural haemorrhage 146–7 subglottic carcinoma 180 submandibular salivary gland
calculi 192–3 infection 190–1 tumours 194–5 subphrenic abscess 396–7 superscan appearance 308 supraglottic carcinoma 180 swan-neck deformity 268 swollen diabetic foot 286–7 swollen joint 261 systemic lupus erythematosus 78 systemic sclerosis 78
T talus fractures 336 technetium scan 12–13 arteriovenous fistula 131 testicular torsion 254 vesico-ureteric reflux 243 testicular cancer 220–1 testicular masses 200 testicular pain 213 testicular torsion 213, 254–5 testicular ultrasound 8 thallium exercise test 28 thoracic aneurysm 104–5 thoracic aorta enlargement 94 thoracic trauma 318–19 thumb fracture/ dislocation 329 thumb-printing 354, 384–5 thyroid cancer 182 thyroid nodules and masses 182–3,9 thyrotrophic cell adenoma 162 tibial plateau fractures 334 transient ischaemic attacks 142 transoesophageal echocardiography (TOE) aortic dissection 102 thoracic aneurysm 104 trans-rectal ultrasound guided biopsy (TRUS) 222 trans-scaphoidperilunate dislocation 328 transudates 74 trauma 311 triangular fibrocartilage complex injury 329 triquetral avulsion fracture 328 triquetrolunate ligament injury 329 tuberculosis 19, 86–7 renal 236
439
U ulcerative colitis 384–5 ultrasound 8; see also endoscopic ultrasound abdominal aortic aneurysm 122–3 abdominal distension 355 abdominal scan 8 abdominal trauma 320 acutely painful blue leg 99 aortic dissection 102 appendicitis 376 arteriovenous fistula 130 ascites 410–11 bladder cancer 216–17 bone pain 260 bone tumours 263 branchial cleft cysts 196–7 breast abscess 422–3 breast cancer 418–19 breast cyst 424–5 cardiac 9; see also echocardiography cardiomyopathy 108 cervical cancer 225 chest pain 28 cholangiocarcinoma 370–1 cholecystitis/ cholangitis 378–9 cirrhosis 408 Crohn’s disease 382 crystal deposition 270 cystic fibrosis 72 ectopic pregnancy 244–5 endometrial cancer 226–7 endometriosis 246–7 epididymitis 252–3 fibroadenoma 426–7 galactocoele 424–5 gastrointestinal lymphoma 366 haematuria 208 hepatocellular cancer 368 hernia 412 hoarse voice 173 hydrocephalus 152 hydronephrosis 9, 207, 209 hyperparathyroidism 184 hypertension 210 hypoxia 39 infective colitis 386 intermenstrual bleeding 211 intermittent claudication 98 interventional procedures 20 intussusception 402–3 jaundice 350
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SUBASH KC/NMC-15TH/2014
440
INDEX ultrasound 8 (cont.) joint replacement, loose/ painful 288 laryngeal carcinoma 180 liver tumours 368 lung abscess 42 lung cancer 62 mediastinal masses 90 nasopharyngeal tumours 176 neck lumps 172 neck scan 9 oropharyngeal tumours 178 ovarian cancer 228, 231 ovarian masses 230 ovarian torsion 248 pancreatic cancer 372 pancreatitis, acute 404 pancreatitis, chronic 406 papilloma 428–9 pelvic inflammatory disease 250–1 pelvic pain, acute 204 pelvic pain, chronic 206 pelvic scan 8, 204 peripheral vascular disease 124 pleural effusion 74 pneumonia 44 pneumothorax 54 postmenopausal bleeding 212 prostate cancer 222 psoas abscess 282 pulmonary embolism 48 rectal cancer 364 renal cell cancer 218 renal failure, acute 207 renal tract calculi 238 renal transplant dysfunction 240–1 rheumatoid arthritis 268 salivary gland infection 190 salivary gland tumours 194
sarcoidosis 82 septic arthritis 284 shortness of breath 33 sialolithiasis 192–3 soft tissue lump 262 stroke 142 subphrenic abscess 396–7 swollen joint 261 testicular cancer 220–1 testicular pain 213 testicular scan 8 testicular torsion 254–5 thoracic aneurysm 104 thoracic trauma 318 thyroid nodules and masses 182–3,9 tuberculosis 87 upper abdominal pain 346 urinary tract scan 8–9 vascular scan 9 vesico-ureteric reflux 242 vomiting 349 Wegener’s granulomatosis 56 weight loss 356 wheeze 31 upper abdominal pain 346 ureter dilation 201 urinary tract ultrasound 8–9 urological fluoroscopy 4–5 urothelial cancer 216–17
vascular presenting syndromes 97 vascular ultrasound 9 venography arteriovenous fistula 130 chronic pelvic pain 206 ventilation/perfusion (V/Q) scan 14 chest pain 29 COPD 46 emphysema 46 haemoptysis 36 hypoxia 39 pulmonary embolism 15, 49 vesico-ureteric reflux 242–3 vestibular schwannoma 154–5 voice hoarseness 173 volvulus 400–1 vomiting 348 von Recklinghausen’s neurofibromatosis 154 voxels 10
W
SUBASH KC/NMC-15TH/2014 V vaginal bleeding intermenstrual 211 postmenopausal 212 valvular disease aortic stenosis 112–13 mitral valve 114–15 vascular conditions 101 vascular differential diagnosis 93 vascular interventions 20–1
Warthin’s tumour 194 Weber–AO classification system 337 Wegener’s granulomatosis 56–7 weight loss 356 wheeze 30 whiteout 24 window level 10 window width 10 wrist trauma 328–30
X xanthogranulomatous pyelonephritis 236 X-rays 2; see also plain film
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